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I n t e g r a t e d C o n t r o l S o l u t i o n s & E n e r g y S a v i n g s
c.pCO
NO POWER
& SIGNAL
CABLES
TOGETHER
READ CAREFULLY IN THE TEXT!
Programmable Controller
User manual
3
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
IMPORTANT
CAREL bases the development of its products on decades of experience in
HVAC, on the continuous investments in technological innovations to products,
procedures and strict quality processes with in-circuit and functional testing on
100% of its products, and on the most innovative production technology available
on the market. CAREL and its subsidiaries nonetheless cannot guarantee that all
the aspects of the product and the software included with the product respond
to the requirements of the fi nal application, despite the product being developed
according to start-of-the-art techniques.
The customer (manufacturer, developer or installer of the fi nal equipment) accepts
all liability and risk relating to the confi guration of the product in order to reach
the expected results in relation to the specifi c fi nal installation and/or equipment.
CAREL may, based on specifi c agreements, act as a consultant for the positive
commissioning of the fi nal unit/application, however in no case does it accept
liability for the correct operation of the fi nal equipment/system.
The CAREL product is a state-of-the-art product, whose operation is specifi ed in the
technical documentation supplied with the product or can be downloaded, even
prior to purchase, from the website www.CAREL.com.
Each CAREL product, in relation to its advanced level of technology, requires setup
/ confi guration / programming / commissioning to be able to operate in the best
possible way for the specifi c application. The failure to complete such operations,
which are required/indicated in the user manual, may cause the fi nal product to
malfunction; CAREL accepts no liability in such cases.
Only qualifi ed personnel may install or carry out technical service on the product.
The customer must only use the product in the manner described in the
documentation relating to the product.
In addition to observing any further warnings described in this manual, the
following warnings must be heeded for all CAREL products:
• Prevent the electronic circuits from getting wet. Rain, humidity and all
types of liquids or condensate contain corrosive minerals that may damage
the electronic circuits. In any case, the product should be used or stored
in environments that comply with the temperature and humidity limits
specifi ed in the manual.
• Do not install the device in particularly hot environments. Too high
temperatures may reduce the life of electronic devices, damage them and
deform or melt the plastic parts. In any case, the product should be used
or stored in environments that comply with the temperature and humidity
limits specifi ed in the manual.
• Do not attempt to open the device in any way other than described in the
manual.
• Do not drop, hit or shake the device, as the internal circuits and mechanisms
may be irreparably damaged.
• Do not use corrosive chemicals, solvents or aggressive detergents to clean
the device.
• Do not use the product for applications other than those specifi ed in the
technical manual.
All of the above suggestions likewise apply to the controllers, serial boards or any
other accessory in the CAREL product portfolio.
CAREL adopts a policy of continual development. Consequently, CAREL reserves
the right to make changes and improvements to any product described in this
document without prior warning.
The technical specifi cations shown in the manual may be changed without prior
warning.
The liability of CAREL in relation to its products is specifi ed in the CAREL general
contract conditions, available on the website www.CAREL.com and/or by specifi c
agreements with customers; specifi cally, to the extent where allowed by applicable
legislation, in no case will CAREL, its employees or subsidiaries be liable for any
lost earnings or sales, losses of data and information, costs of replacement
goods or services, damage to things or people, downtime or any direct, indirect,
incidental, actual, punitive, exemplary, special or consequential damage of any
kind whatsoever, whether contractual, extra-contractual or due to negligence, or
any other liabilities deriving from the installation, use or impossibility to use the
product, even if CAREL or its subsidiaries are warned of the possibility of such
damage.
DISPOSAL
INFORMATION FOR USERS ON THE CORRECT HANDLING OF WASTE ELECTRICAL AND ELECTRONIC EQUIPMENT (WEEE)
In reference to European Union directive 2002/96/EC issued on 27 January 2003
and the related national legislation, please note that:
• WEEE cannot be disposed of as municipal waste and such waste must be
collected and disposed of separately;
• the public or private waste collection systems defi ned by local legislation must
be used. In addition, the equipment can be returned to the distributor at the
end of its working life when buying new equipment;
• the equipment may contain hazardous substances: the improper use or
incorrect disposal of such may have negative eff ects on human health and on
the environment;
• the symbol (crossed-out wheeled bin) shown on the product or on the
packaging and on the instruction sheet indicates that the equipment has
been introduced onto the market after 13 August 2005 and that it must be
disposed of separately;
• in the event of illegal disposal of electrical and electronic waste, the penalties
are specifi ed by local waste disposal legislation.
Warranty on the materials: 2 years (from the date of production, excluding
consumables).
Approval: the quality and safety of CAREL INDUSTRIES Hqs products are
guaranteed by the ISO 9001 certifi ed design and production system.
WARNING: separate as much as possible the probe and digital input signal
cables from the cables carrying inductive loads and power cables to avoid
possible electromagnetic disturbance.
Never run power cables (including the electrical panel wiring) and signal
cables in the same conduits.
NO POWER
& SIGNAL
CABLES
TOGETHER
READ CAREFULLY IN THE TEXT!
4
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
5
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Content
1. INTRODUCTION 7
1.1 Functional layout .......................................................................................................................................... 8
1.2 Terminals ............................................................................................................................................................. 9
1.3 BMS port expansion cards (c.pCO Small...Extralarge) ............................................................... 9
1.4 Fieldbus port expansions cards (c.pCO Small...Extralarge) .................................................10
1.5 External modules..........................................................................................................................................10
2. DESIGN 11
2.1 c.pCO design ..................................................................................................................................................11
3. COMMUNICATION PORTS 13
3.1 Serial ports ........................................................................................................................................................13
3.2 Ethernet ports ................................................................................................................................................14
3.3 Controller network connections ........................................................................................................14
4. INSTALLATION 15
4.1 Mounting and dimensions ...................................................................................................................15
4.2 Installation ........................................................................................................................................................16
4.3 Preliminary operations ..............................................................................................................................17
4.4 Electrical connections ...............................................................................................................................17
4.5 Connecting the terminal .........................................................................................................................19
4.6 Input/output labels.....................................................................................................................................20
4.7 I/O table .............................................................................................................................................................21
4.8 c.pCOmini e c.pCOe : connections terminals .............................................................................22
4.9 c.pCO Large and Extralarge: connection terminals ................................................................25
5. INPUT/OUTPUT CONNECTIONS 28
5.1 Power supply ..................................................................................................................................................28
5.2 Universal inputs/outputs .........................................................................................................................28
5.3 Digital inputs ...................................................................................................................................................31
5.4 Analogue outputs ........................................................................................................................................33
5.5 Connecting the Ultracap module ......................................................................................................34
5.6 Connecting the electronic valve ........................................................................................................35
5.7 Digital outputs ...............................................................................................................................................36
5.8 Solid state relay (SSR) digital outputs .............................................................................................37
5.9 General connection diagram c.pCOmini ......................................................................................38
5.10 General connection diagram c.pCO .................................................................................................39
6. START-UP 40
6.1 Switching on ...................................................................................................................................................40
6.2 Private and shared terminal ...................................................................................................................40
6.3 Setting the controller pLAN address ................................................................................................40
6.4 Setting the terminal address and connecting the controller to the terminal ......41
6.5 Sharing terminals in a pLAN network..............................................................................................41
6.6 Uploading/updating the software ....................................................................................................42
6.7 c.pCOe expansion board: installation and confi guration ...................................................45
7. SYSTEM MENU 46
7.1 Menu tree..........................................................................................................................................................46
8. PROTECTION: PASSWORD AND DIGITAL SIGNATURE
MANAGEMENT 48
8.1 Protection features ......................................................................................................................................48
8.2 Protection Password .................................................................................................................................48
8.3 Digital signature generation .................................................................................................................49
8.4 Loading an application program on a controller signed with digital signature ...50
8.5 System menu password...........................................................................................................................50
6
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
9. ACCESS MANAGEMENT FOR IP SERVICES 51
9.1 Accounts management ...........................................................................................................................51
9.2 Computer - c.pCO connection ............................................................................................................52
9.3 FTP connection with authentication ...............................................................................................52
9.4 HTTP connection with authentication ...........................................................................................53
10. WEB SERVER AND TERA CLOUD PLATFORM 54
10.1 Web kit download and installation ...................................................................................................54
10.2 Contents of the package .........................................................................................................................54
10.3 Web pGD ...........................................................................................................................................................54
10.4 Variables table ................................................................................................................................................55
10.5 Variable trend (logger) ..............................................................................................................................55
10.6 c.pCO connection to cloud tERA ........................................................................................................55
11. EXAMPLES 56
11.1 Devices that can be connected to the c.pCO ............................................................................58
12. TECHNICAL SPECIFICATIONS 58
12.1 c.pCO technical specifi cations .............................................................................................................58
7
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
1. INTRODUCTION
c.pCO is a microprocessor-based, programmable electronic controller,
featuring a multitasking operating system, compatible with the c.pCO
Sistema family of devices, which includes programmable controllers, user
terminals, gateways, communication devices and remote management
devices. These devices represent a powerful control system that can be
easily interfaced with most Building Management Systems (BMS) available
on the market. The controller has been developed by CAREL to provide
solutions for several applications in air-conditioning, refrigeration and
HVAC/R in general. Its fl exibility allows for creation of tailor made control
solutions according to customer specifi cations. Compared to pCO sistema,
the range is enhanced by a new compact controller, and consequently
comprises the c.pCOmini (4 DIN module and panel mounting version),
featuring 10 universal inputs/outputs and available with built-in driver for
single-pole electronic expansion valve, as well as the c.pCO Small, Medium,
Large, ExtraLarge models. The number of inputs/outputs can be increased
by connecting a c.pCOe expansion board.
Medium size controllers can feature also one or two built-in drivers for
electronic expansion valves. The Ultracap module (accessory) can be used
as an emergency power supply for valve drivers, so as to ensure total closure
of the valves in case of power failures (alternating current).
c.pCO can be connected in an Ethernet LAN to other c.pCO family
controllers. Each device in the LAN can exchange digital or analogue
variables with all the others, based on the application program used. c.pCO
can also be connected via a pLAN (pCO Local Area Network) to the pGD
range of terminals.
Each Fieldbus serial port, whether built into the controller or installed
via an optional card, can be connected to controlled fi eld devices such as
valve and damper actuators and external drivers (e.g. drivers for electronic
expansion valves, EVD Evolution).
Each BMS serial port, whether built into the controller or installed via
an optional card, can be connected to fi eld-level, automation-level
or management-level standard bus systems, such as Konnex®, LON®,
BACnet™, etc.
The real-time operating system (OS) manages priorities so as to ensure the
application program cycle time, 32-bit data and fl oating point numbers, and
the Ethernet multimaster and multi-protocol connection.
Main features:• optimization of the memory occupied by the Operating System and
the application program, of the boot time, of the time for loading the
application program and of the cycle time;
• system response time optimization: the controller executes several
processes in parallel, each managed with a diff erent priority;
• independent processes: each process, whether a protocol, USB port
management, data and alarm log (datalogger), data exchange with
tERA cloud service, works independently of the others;
• runtime debug (on target)
• native management of TCP/IP multitasking protocol
Local connectivity: • built-in web server, completely customisable, supports HTML standard
and JavaScript. The 90 Mbyte memory can be used to store pages
created using the most common website development tools. Dynamic
methods (CGI, Common Gateway Interface) are available to read and
write the application program variables. Other innovative functions
include: the possibility to display the contents of the pGD1 terminal
in the browser, display graphs of data recorded by the datalogger and
plot data from probes and energy meters in real time (variable trends);
• fi le server (FTP): the c.pCO public fi le system can be accessed in the
local network via FTP. Consequently, an FTP client can be used to
connect to the controller so as to upload updates, web pages and
documents. The “.csv” (comma separated value) fi les exported by the
datalogger can be downloaded
• creation of accounts with diff erent access privileges, associated to
both a webserver and an FTP server;
• management of multiple simultaneous instances of Modbus TCP/IP
Master and Slave protocol;
• management of BACnet™ protocol with B-BC profi le (MSTP or TCP/IP,
license to be purchased separately).
Remote connectivity:• integrated connectivity to the Carel tERA cloud service: by connecting a
normal router to the controller, a secure connection can be established to
the tERA server. Remote services can be activated for the management
of control variables, alarm notifi cation, data analysis and reports. The
connections are encrypted using the SSL (Secure Socket Layer) standard, in
compliance with NIST, international reference for information security over
the internet.
• a fi rewall guarantees remote access only via a secure connection (tERA
cloud connection or encrypted VPN)
Integrated USB peripheral: it can be used to update the controller and
save web pages, documents and applications in the fl ash memory. Also
used to download the logs from the controller.
• c.pCO Small...Extralarge: the host and device USB ports are managed
directly by the operating system. USB host (top): a USB fl ash drive can
be used to load updates (operating system/application program) on
the controller. USB device port (bottom): by connecting c.pCO to a
personal computer, its memory is made available as a removable drive,
and at the same time a communication channel is established with the
c.suite software for programming and online debugging.
• c.pCOmini: the 2 USB ports are physically integrated into a single micro
USB port; the same performance is available as for the two ports on
the larger models.
Other features:• the same controller can be connected to up to 3 pGD1/pGDE terminals;
• external or built-in terminal with display and keypad with LED backlit
buttons, can be used for uploading software and commissioning;
• universal inputs/outputs confi gurable via an application program,
for connecting active and passive probes, digital inputs, analogue
and PWM outputs. This extends the possibilities of confi guring
inputs/outputs without having to install a larger controller;
• possibility to use the c.suite software development environment,
installable on a personal computer, for creating and customising the
application program, simulating operation, supervising performance
and confi guring the Ethernet network;
• wide range of models that diff er in terms of:
• size (mini, Small, Medium, Large and Extralarge), to ensure maximum
fl exibility according to the application;
• digital outputs (24/230 V relay) and SSR (solid state relay);
• NO or NC relay outputs
• integrated optically-isolated/not optically-isolated serial ports;
• optional built-in display;
• various types of connectors (spring, screw, etc.).
Software programming suite, c.suite: designed as a set of independent
modules, one for each phase in HVAC/R software development, c.suite
allows teams of professionals with diff erent skills to work in a group on
the same project, increasing effi ciency and adopting joint development
based on workfl ow. All the software modules cooperate with each other
based on centralised data exchange, optionally managed by a software
version number (SVN):
• c.strategy: environment where expert algorithm programmers prepare
the core of the application program. Features of the programming
environment:
- total independence of programming logic from the hardware and
the connected devices;
- availability of IEC 61131 standard languages: ST (structured text), FBD
(function block diagram), SFC (sequential function chart), LD (Ladder
diagram), which can also be used simultaneously;
- datatype management: 32-bit, fl oating point, array and native
structures;
- debug on target via USB port or Ethernet;
• c.mask: dedicated environment for developers of the user interface.
• c.design: defi nition of confi gurations, such as controller type and size,
type of inputs/outputs, master/slave protocols, default parameter values,
datalogger, network address and user management, connection to tERA
cloud services.
• c.factory: used to program the controller, loading the application program
and the appropriate unit confi guration during assembly.
8
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
Applications
When provided with a dedicated application program, the controller can be used
to control diff erent kinds of equipment:
• chillers and heat pumps;
• roof-top units;
• air-conditioners;
• small/medium-sized air handling units (on request);
• refrigerated showcases (on request and to specifi cations);
• cold rooms (on request and to specifi cations);
• curing rooms;
• compressor racks;
• universal stage controllers.
1.1 Functional layoutThe fi gure below shows the functional layout of an air handling unit. Damper
actuators and valve actuators are fi eld devices that communicate through
Fieldbus 1 (ref. C). Fieldbus 2 (ref. E) is the medium through which the serial probes
communicate the values measured, and through which the humidifi er control
board and the fans exchange data and receive set points from the controller. The
built-in terminal and the remote terminal, which communicate via pLAN (ref. A),
are used for installing the application program and for commissioning the system.
The PGD touchscreen terminal, intuitive and simple to use, can be used while the
unit is normally working to set switch-on and switch-off times, to enter the main
parameters, to perform other advanced functions of the application program and
to view any alarms triggered. In this case data are exchanged via Ethernet port (ref.
D). In the same network it is possible to connect another c.pCO controller as well
as to communicate with remote cloud service tEra or to BACnet™ supervisor. The
system can be connected to other supervision systems (Konnex®, LON®, etc.) after
installing the relative BMS1 expansion card (ref. B).
584SRsutats
GNX RS485+ –P1 P2 P3
B A Cnet™ MS/TP
FieldBus 1 BMS 1
J1 J24 J2 J3 J4 J5 J7 J8
J20
J21
J14
J10
J13J12
J22
J16 J17 J18J15
J6
J19Fie ldB us car d B M S card
J23 FBus2
J11 pLAN
J25 BMS2 J26 FBus24 3 2 1
touch screen
pGD1
FieldBus 2
Ethernet
pLAN
A
D E
C B
EVDevolution
c.pCOe
c.pCO mini
tERA cloudservice
Power +FANEVD Evolution
PC
BELIMO
BELIMO
tDisplay, tService
F
Router
RS485 serial card
FieldBus serial card
Damper servo-control
Servo-control valve
Serial probes th-Tune
Access Point Speed regulator
pGD terminal
Humidifier control board
Serial probesThird part
device
interface
interface
interface
interfaceBACnet™ RS485
Ethernet™ /BACnet™
LonWorks ®
Konnex ®
Fig. 1.a
Ref. Serial port/Connectors Connection to:A pLAN/J10, J11 up to 3 terminals (e.g. pGD1, pLDPRO)
B BMS 1 Serial Card a building automation system, after installing the special BMS card (see par. 1.3)
C FieldBus 1 Serial Card sensors, actuators, etc., on a Fieldbus, after installing the special card (see par. 1.4)
D Ethernet pGD Touch terminals, c.pCO controllers, Router-->tERA
E FieldBus 2 / J26 (e J23 in Large, Extralarge models) sensors, actuators, etc., on a Fieldbus (built-in card)
F BMS 2 / J25 other devices (built-in card)
9
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
1.2 Terminals
P/N Description Notes
PGDT04000F***
(tech. leafl et
+050001475)
pGD Touch 4.3” user
terminal
The pGD Touch 4.3” graphics terminal belongs to the family of touchscreen terminals, designed to
simplify and make more intuitive the interfacing of users with the controllers of the pCO Sistema
family. The electronic technology applied and the new 65,000-colour display allows the terminal
to handle high-quality images and advanced functions, providing an excellent aesthetic perfor-
mance. In addition, the touchscreen panel facilitates man-machine interaction, making it easier
to navigate through the various screens.
PGDT07000F***
(tech. leafl et
+050001490)
pGD Touch 7” user
terminal
See description of pGD Touch 4.3” user terminal.
PGDE000*
(tech. leafl et
+050001450)
pGD graphic terminal Allows complete graphics management through the use of icons (defi ned during the development
of the application software) and management of international fonts in two sizes: 5x7 and 11x15
pixels. The application software resides only on the c.pCO controller; the terminal requires no addi-
tional software for operation. Accessories for installation:
• telephone connection cable P/N S90CONN00*;
• connection cable for c.pCOmini P/N S90CONN0S0;
• TCONN6J000 connection card (technical leafl et +050002895).PLD**GFP00
(tech. leafl et
+050001840)
pLDPRO graphic
terminal
Allows complete graphics management through the use of icons (defi ned during the
development of the application software) and management of international fonts in two sizes:
6x8 and 12x16 pixels and audible signal via buzzer. The application software resides only on the
c.pCO controller; the terminal requires no additional software for operation, and is compatible
with graphic interfaces developed for the pGD graphic terminal. Accessories for installation:
• telephone connection cable P/N S90CONN00*;
• connection cable for c.pCOmini P/N S90CONN0S0;
• TCONN6J000 connection card (technical leafl et +050002895).
PGD1000I00
(tech. leafl et
+050001055)
Graphic terminal
(panel installation)
This model can be installed on the panel. Its graphics properties are identical to those of the
PGDE000 terminal*. Accessories for installation:
• telephone connection cable, code S90CONN00*;
• TCONN6J000 shunt card (instructions sheet code +050002895).
AT*
(tech. leafl et
+0500016IE/
+0500017IE)
th-TUNE, terminal
for panel or wall
installation
Allows the user to adjust the temperature and humidity in residential environments. th-Tune is
compatible with the main wall-boxes found in many countries (Italy, U.S., Germany, China).
1.3 BMS port expansion cards (c.pCO Small...Extralarge)
P/N Description NotesPCOS004850
(tech. leafl et
+050003237)
BMS RS485 serial
card
Can be installed on all controllers of the pCO family (except pCOB); allows direct interfacing with
an RS485 network, max. baud rate 19200. The card ensures the controller optical isolation from
the RS485 serial network.
PCO1000WB0
(tech. leafl et
+050003238)
Ethernet - pCOweb
interface card
Can be installed on all controllers of the pCO family (except pCOB); allows connecting the con-
troller to a 10 Mbps Ethernet network and provides the following functions:
• access to controller data (network variables and parameters) through an Internet browser (e.g.
Internet Explorer™) installed on a PC and connected to the network via TCP/IP to pCOWeb;
• connection to a supervisor network running the protocols indicated in the instructions sheet.
PCO1000BA0
(tech. leafl et
+050000930)
BACnet MS/TP -
pCOnet interface
card
Allows connecting the controller to a BACnet MS/TP (Master/Slave Token pass) network. The
RS485 connection is optically isolated from the controller.
PCO10000F0
(tech. leafl et
+050004045)
LonWorks® interface
card
Allows connecting to a LonWorks® TP/FT 10 network. The program resides in the fl ash memory
located in the socket, and can be programmed directly via the LonWorks® network using net-
work installation and maintenance tools such as LonMaker™. Information on how to program
the card is available in the relative manual, code +030221960.
PCOS00KXB0
(tech. leafl et
+050000770)
Konnex interface
card
Allows connecting to a network set up according to the Konnex® standard. Two versions
available: for BMS port and Fieldbus port.
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
1.4 Fieldbus port expansions cards (c.pCO Small...Extralarge)
P/N Description NotesPCO100FD10
(tech. leafl et
+050003270)
RS485 serial card Allows connecting to an RS485 network (through an electrically isolated interface). The control-
ler consequently acts as a MASTER (i.e. supervisor), therefore other controllers or devices can be
connected as SLAVES. Up to 64 devices can be connected.
PCOS00KXF0
(tech. leafl et
+050000770)
Konnex interface
card
See description of PCOS00KXB0 serial card (previous paragraph).
1.5 External modules
P/N Description NotesPCOS00UC20
(tech. leafl et
+0500041IE)
Module
Ultracap for c.pCO
built-in driver
In case of power failures the module ensures a temporary power supply for the driver only, for
the time necessary to immediately close the electronic valves connected (one or two). This
avoids having to install a solenoid valve or backup battery kit in the refrigerant circuit.
EVD0000UC0
(tech. leafl et
+0500042IE)
Module Ultracap
external
This module, mounted on a DIN rail, can be used as alternative to the Ultracap module (PCO-
S00UC20). It can also be used in applications with a controller without built-in driver for elec-
tronic expansion valves (e.g. pCO Small + EVD Evolution + external Ultracap module). If used
with c.pCOmini, the module ensures a temporary power supply for the driver only, for the time
necessary to close the electronic valve (see technical leafl et +0500058IE)
EVD0000E*
(tech. leafl et
+050004150)
Driver for electronic
expansion valve
The driver for electronic expansion valves with two-pole stepper motor is a controller that ma-
nages refrigerant expansion in a refrigerant circuit. With the c.pCO family controllers, the version
with Modbus/Carel RS485 serial port is required. Alternatively, the driver can work in stand-alone
mode.
CPY*
(manual cod.
+040000030)
Humidifi cation board
KUE CAREL
Used to manage an immersed electrode humidifi er and share the main parameters across a
CAREL/Modbus RS485 serial line. Equipped with:
• all the inputs and outputs required to completely and independently control the humidifi er;
• three LEDs to indicate: alarms (red), steam production (yellow), 24 Vac power supply (green);
• can be connected to the CPY terminal (CPYTERM*) or to the supervisor network with Modbus®
RTU or CAREL proprietary protocol.
PCOUMI2000
(tech. leafl et
+050003210)
Interface for OEM
series humidifi ers
Used to control the main parameters on CAREL OEM humidifi ers directly from the c.pCO
controller. The values measured by the sensors (high level, supply water conductivity, power
consumption sensor) are converted into signals that are compatible with the inputs on the
controller.
P+E*
(tech. leafl et
+0500059IE) c.pCOe expansion
card
Used to increase the number of inputs/outputs on the controller and the number of relays.
emeter1/
emeter3
(tech. leafl et
+0500046ML/
+0500047ML)
Single-phase/three-
phase energy meter
Single-phase/three-phase energy meter with LCD to display parameters; ideal for measuring
active energy and splitting costs. Supplied with RS485 port (Modbus protocol RTU).
FCR3
(tech. leafl et
+050004065)
Three-phase speed
control
The FCR series devices are three-phase electronic voltage controllers that use phase control to
adjust the output voltage supplied to the load, based on the input signal. These devices can
control asynchronous electric motors on fans.
WS01AB2M2*
(tech. leafl et
+0500030ML)
Access point
The Access Point is part of the rTM SE system (Remote Temperature Monitoring) and allows
communication between devices via Modbus® protocol (c.pCO sistema, PlantVisor) and wireless
sensors (WS01*) or other routers (WS01*).
DPW*, DPP*, DPD*
(tech. leafl et
+050001235,
+050001245)
Serial probes
The DP* series temperature and humidity probes for rooms, service environments and duct have
been developed for the residential and light industrial HVAC/R market.
The range includes models with 0 to 10 V output and RS485 serial output (Carel or Modbus).
11
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
2. DESIGN
2.1 c.pCO designOn the models where they are included, the front panel contains a display and a
keypad with 6 backlit buttons that, when pressed individually or in combination,
allow the following operations:
• uploading an application program;
• commissioning.
During regular operation and depending on the application program installed,
the terminal can be used:
• to edit the main operating parameters;
• to display the quantities measured, the active functions and any detected
alarm.
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J20
J21
J14
J10
J13J12
J22
J16 J17 J18J15
J6
J19
NO
14 C14
NC1
4
NO
15 C15
NC1
5
C16
NO
16
NO
17
NO
18 C16
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
J23 Fus2
J11 pLAN
J25 BMS2 J26 FBus2
4 3 2 1
A B C D
VBAT
G0
G
J30
GN
D
VREF
S1 S2 S3 S4 DI1
DI2
J29
only model with built-in driver
only model with built-in driver
J27
1 3 2 4
J28
1 3 2 4
A B D
H
C
G
FE
000A5C*
LMM N
U1 U2 U3 GND
U4 U5 U6 GND
U7 U8 U9 U10
GNDJ1 J2
G G0 Vbat
NO
1
C1/2
NO
2
NO
3
C3/4
/5
NO
4
C3/4
/5
NO
5
NO
6
NC6 C6
+5VR
EFGN
D+V
dc
J9
J10 J11 J12
G/G0: 24 V~ 50...60 Hz / 28...36 V 30 VA/12W
J3 Disp.
+Vterm
J4 FBus
Y1GND
ID2
ID1
Y2 GNDJ8J7
J5 CAN
L H
A
F
P
B
H
F
N
Verde/GreenLink/Act
Giallo/Yellow On = 100MbpsOff = 10Mbps
MMN
OffOff 1= 10Mb0Mbpsps
panel mounting DIN rail mounting
000A5C*
L
c.pCO mini c.pCO Small...Extralarge
J3 Disp
+Vterm
J4 FBus
NO1
C1/2
NO2
NO3
C3/4/5
NO4
C3/4/5
NO5
NO6
NC6
C6
J10J11
J12
U1
U2
U3
GND
U4
U5
U6
GND
U7
U8
U9
U10
GND
J1J2
GG0Vbat
J7
+5VREFGND+V dc J9
Y1GND
ID2ID1
Y2GND
J8
J5 CAN
LH
NM
P
Fig. 2.a
Key:
A Button to set pLAN address G Device USB port (slave) B Display pLAN address H Main displayC Power LED L MAC address labelD Overload LED M Ethernet portE Jumpers to select FieldBus/BMS on port J26 N Ethernet port spadesF Host USB port (master) P Single-pole valve connector
Each controller is provided with connectors for the inputs/outputs (see chap. 5) and
the secondary display, which has a button and a LED for setting the pLAN address.
Depending on the model, it can be supplied with a built-in terminal and USB ports.
Keypad
Button Descr. Backlighting FunctionsAlarm
White/Redpressed together with Enter, accesses the screens managed by operating system.
PrgWhite/Yellow
-
EscWhite
go back up one level
UPWhite
increase the value.
EnterWhite
confi rm the value
DOWNWhite
decrease the value
Select pLAN
address -
• pressed briefl y: the pLAN address is displayed brighter
• pressed repeatedly: increase the address
• release: after a few seconds, the brightness is dimmed and the pLAN address is saved
Note: Once the application program is installed, all button functions depend on the program and do not necessarily correspond to the descriptions above.
12
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Display (c.pCO Small...Extralarge)
Two displays are available:
• the main display on the built-in terminal (if featured);
• the secondary display, which shows the controller pLAN address.
Display (c.pCOmini)
A built-in display is available (if featured), or a secondary display that
displays the controller pLAN address.
LED (c.pCO Small...Extralarge)
Six LEDs are featured:
• 1 yellow LED indicating that the device is powered;
• 1 red LED indicating an overload on the +VDC (J2-5) terminal;
• 4 LEDs indicating valve status (only on c.pCO built-in driver models).
Flashing LEDs mean the valve is moving; steady on LEDs mean the
valve is completely open or closed.
LED Colour DescriptionA Yellow close valve A (connector J27)
B Green open valve A (connector J27)
C Yellow close valve B (connector J28)
D Green open valve B (connector J28)
Microswitches (c.pCO Small...Extralarge)
Four microswitches are provided to confi gure port J26 as a Fieldbus or
BMS port (see “Port J26 confi guration”).
USB ports
c.pCO Small...ExtralargeThe controller features two USB ports, which can be accessed after
removing the cover in order to performe operations such as loading the
application program and the operating system, saving the logs, etc.
• a “host” USB port for connecting pendrives;
• a “device” USB port for direct connection to the USB port of a computer.
c.pCOminic.pCOmini models features a single micro USB port for operations such
as loading the application program and the operating system, saving the
logs, etc.
• the same USB port acts both as “host” port for connecting a USB fl ash
drive, as well as “device” port for direct connection to a computer.
Mac Address label
Label with QR code containing the Mac Address that uniquely identifi es
the controller on the Ethernet network
NO
1
C1/2
NO
2
NO
3
C3/4
/5
NO
4
C3/4
/5
NO
5
NO
6
NC6 C6
J10 J11 J12
J3 Disp.
+Vterm
J4 FBus J5 CAN
L H
Mac Address
Fig. 2.b
13
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
3. COMMUNICATION PORTS
3.1 Serial ports
c.pCO Small...Extralarge
The controllers come with fi ve serial ports:
• a terminal port on connector J10-J11 (pLAN)
• a built-in BMS port on connector J25 (BMS2)
• a built-in Fieldbus port on connector J26 (FBus2).
• a BMS port to be used with the c.pCO family BMS expansion card (BMS1)
• a FieldBus port to be used with the c.pCO family BMS expansion card (FBus1)
On the c.pCO Large and Extralarge version, connector J23 is available, marked
FBus2, in the same way as connector J26. From the point of view of application
program management, this is the same serial line, so diff erent addresses must be
used for devices connected to both connectors, while from the electrical point of
view the ports are independent (an electrical fault on port J26 does not aff ect port
J23). See the “Technical Specifi cations” table (chap. 12).
c.pCOmini
The controller features:
• a terminal port on connector J3 (Disp.)
• a built-in BMS port on connector J6 (BMS, only on the c.pCOmini Enhanced
model)
• a built-in Fieldbus port on connector J4 (FBus, on the c.pCOmini Enhanced and
High End models).
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7
J8
J20
J21
J14
J10
J13J12
J22
J16 J17 J18J15
J6
J19
NO
14 C14
NC1
4
NO
15 C15
NC1
5
C16
NO
16
NO
17
NO
18 C16
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
J23 FBus2
J11 pLAN
J25 BMS2 J26 FBus24 3 2 1
ONLY FOR LARGE AND EXTRALARGEMODELS
U1
U2
U3
GN
D
U4
U5
U6
GN
D
U7
U8
U9
U10
GN
DJ1 J2
G G0
Vbat
NO
1
C1/2
NO
2
NO
3
C3/4
/5
NO
4
C3/4
/5
NO
5
NO
6
NC6 C6
+5VR
EFG
ND
+V d
c
J9
J10 J11 J12
G/G0: 24 V~ 50...60 Hz / 28...36 V 30 VA/12W
J3 Disp.
+Vterm
J4 FBus
Y1GN
DID
2ID
1
Y2 GN
D
J8J7
J5 CAN
L H
000A5C*
Fig. 3.a
Interface Type/Connectors Control FeaturesEthernet RJ45 c.pCOmini High End • one 10/100 Mbps Ethernet port
c.pCO Small...Extralarge • two equivalent 10/100 Mbps Ethernet ports (100-BASE TX standard)Serial ZERO J3 Disp. c.pCOmini • Integrated on main boardSerial ZERO pLAN/J10, J11 c.pCO Small...Extralarge • HW driver: asynchronous half duplex RS485 pLAN
• Not optically-isolated• Connectors: telephone jack + 3-pin plug-in connector (4-pin plug-in connector only on c.pCOmini)
Serial ONE BMS 1 Serial Card c.pCO Small...Extralarge • Not integrated on main board• HW driver: not present• Can be used with all c.pCO family BMS expansion cards
Serial TWO FieldBus 1 Serial Card c.pCO Small...Extralarge • Not integrated on main board• HW driver: not present• Can be used with all c.pCO family Fieldbus expansion cards
Serial THREE J6 BMS c..pCOmini Enhanced • Integrated on main boardBMS 2 / J25 c.pCO Small...Extralarge • HW driver: asynchronous half duplex RS485 Slave
• Optically-isolated/non-optically-isolated serial port• 3-pin plug-in connector
Serial
FOUR
J4 FBus c.pCOmini Enhanced
and High End
• Integrated on main board• HW driver: asynchronous half duplex RS485 Master
FieldBus 2 / J26
(and J23 Large - Extra-
large version)
c.pCO Small...Extralarge • Integrated on main board• HW driver: asynchronous half duplex RS485 Master or Slave (see par. " J26 port confi guration")• J23: not optically-isolated• J26: optically-isolated/not optically-isolated• 3-pin plug-in connector• J23 and J26 are both managed by the same protocol as serial 4, with the advantage of being
electrically independent.
Tab. 3.a
14
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Port J26 confi guration (c.pCO Small...Extralarge)
c.pCO Small...Extralarge controllers are provided with 4 microswitches for
confi guring serial port J26 (see fi gure):
• microswitches all down: port J26 set with Fieldbus hardware;
• microswitches all up: port J26 set with BMS hardware*.
Factory confi guration: Fieldbus port.
(*) To use the serial port as a BMS connector, the correct communication
protocol needs to be set in the application, using the c.suite
programming environment.
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
FieldBus
4 3 2 1BMS
1 2 3 4BMS
FieldBus
J26
J26
Fig. 3.b
3.2 Ethernet portsThe c.pCO Small...Extralarge controllers have two 10/100 Mbps/s Ethernet
ports. These two ports are connected internally via a switch that automatically
forwards any pass-through traffi c not addressed to the controller. If the
controller is not powered, pass-through between the two ports will be
interrupted. The two ports feature auto crossover (Auto-MDIX). The c.pCOmini
High End controller features one 10/100Mbps/s Ethernet port.
3.3 Controller network connectionsMultimaster or Master/Slave networks of c.pCO controllers can be created
using the Ethernet ports and the serial ports:
Connection via Ethernet portThe built-in Ethernet ports on the c.pCO can be used to create multimaster
and multiprotocol networks, with transmission speeds up to 100 Mbps.
The controllers can be connected together via an external switch (see the
fi gure below). For c.pCO Small...Extralarge models, the two Ethernet ports
are connected by an internal hub-switch, meaning a daisy-chain network
can be created without needing an external switch (see fi gure 3.c).
PlantVisorPro
Switch
J3 Disp
+Vt
erm L H
J4 FBus J5 CAN J3 Disp
+Vt
erm L H
J4 FBus J5 CAN
PGD terminaltouch screen
c.pCO mini
max 100 m
c.pCO mini
J25 BMS2 J26 FBus2
J11 pLAN
c. pCO
MASTER
J25 BMS2 J26 FBus2
J11 pLAN
c.pCOJ25 BMS2 J26 FBus2
J11 pLAN
c.pCO
MASTER MASTERPC
Switch
J25 BMS2 J26 FBus2
J11 pLAN
c. pCO
MASTER
J25 BMS2 J26 FBus2
J11 pLAN
c.pCOJ25 BMS2 J26 FBus2
J11 pLAN
c.pCO
MASTER MASTERPC
max 100 m max 100 mmax 100 m
Fig. 3.c
Connection via serial ports:A master/slave network of c.pCO controllers can be created by using the
RS485 serial ports. Such networks comprise:
• one c.pCO controller (Master) that communicates via the Fieldbus
RS485 serial port using Carel Master or Modbus Master protocol;
• one or more c.pCO controllers (Slaves) connected to the point-to-point
network via the BMS RS485 serial port using Carel Slave or Modbus
Slave protocol.
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
MASTER
J25 BMS2 J26 FBus2
J11 pLAN
c.pCOJ25 BMS2 J26 FBus2
J11 pLAN
c.pCO
MASTER - SLAVE network
SLAVE SLAVE
PCMASTER
J25 BMS2 J26 FBus2
J11 pLAN
c.pCOJ25 BMS2 J26 FBus2
J11 pLAN
c.pCO
SLAVE SLAVE
Fig. 3.d
Important warnings:1. By applying appropriate impedance, a serial port with Master
hardware (FBus) supplies the network with the bias voltage required
to run all the connected devices, i.e. the master itself and its slaves;
conversely, serial ports with slave hardware (BMS) do not provide bias
voltage, so it is always advisable to connect at least one device with
master hardware (FBus) to the network so that it is correctly biased;
2. However, no more than two devices with master hardware (FBus)
can be connected to the same network, otherwise the network total
bias impedance becomes too small and incapable of supplying the
required voltage to the RS485 network.
3. It is recommended to connect the serial probes or other fi eld devices
to an optically-isolated version of the Fieldbus serial port or to serial
port TWO – Fieldbus 1 to exploit the fi ltering properties of optical
isolation.
Special cases• In networks consisting only of Master HW devices, no more than 2
devices can be connected. The max. length allowed for the network
is 1000 m. If the network is longer than 100 m, apply the 120Ω, 1/4W
terminating resistors to the fi rst and last devices in the network;
• connect the computer to a network with no more than 1 master HW
device or no more than 207 slave HW devices.
15
c.pCO
A
11045
B
44
pGDE pGD1
156
125
67
18
30
82
202 53
43
177
70 63
110
132
45
c.pCO mini c.pCO mini, panel mounting
148
82
70.5
81.0
59.5
38.1
134
Ø 4
34.5
dima di foraturadrilling template
127x69 mm
Ø 4
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
4. INSTALLATION
4.1 Mounting and dimensionsAll models in the c.pCO family can be mounted on a DIN rail, except for
the c.pCOmini panel version.
DIN rail assembly: c.pCOmini, c.pCO Small...Extralarge
The following fi gure shows the dimensions of the c.pCO controllers,
according to the model.
Mounting:
• place the controller on the DIN rail and press it down gently. The tabs
at the back will snap into place and lock the controller.
Removing:
• lift the tabs using a screwdriver applied to their release slots. The tabs
are kept in place by springs.
Fig. 4.a
Dimensions (mm)Small Medium Buit-in driver Large Extralarge
A 227,5 315 315 315 315B 60 60 60 60 60
B - with USB port /
built-in terminal70 70 70 70 70
B - with ULTRACAP
module- - 75 - -
Tab. 4.a
16
3
D D
D D
E
E
E
E
4a
4b
vista da dietrocontroller
sideview from behind
A
B
C
C
controllerside
1
2
34
guarnizione lato a righestriped side gasket
CLICK !
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Fig. 4.b
Note:• for correct assembly, follow the instructions shown in the following
diagram.
• Important: when assembling, make sure that the frame is securely in
place on all four sides.
• if needing to remove the frame, use a screwdriver to lever it off in slot C.
• to access the USB port, open the cover B and lift the rubber cap A
using the tab
• before closing the cover B again, make sure the rubber cap A is properly
inserted (it must be flush with the outer plastic surface).
• if needing to cut sheet metal, it is recommended to use laser cutting;
• the thickness of the sheet metal or the material used to make the
electrical panel must be suitable to ensure safe and stable installation
of the terminal;
• the tension applied by the screws must not cause deformation of the
sheet metal, so as to not compromise the degree of protection (IP)
shown in the specifications. This degree of protection is guaranteed in
the following conditions: maximum deviation of rectangular opening
from flat surface ≤ 0.3mm, maximum roughness of the surface where
the gasket is applied ≤ 120 m.
4.2 Installation
Environmental conditionsAvoid installing the controller and the terminal in places with:
• exposure to direct sunlight and to the elements in general;
• temperature and humidity outside the product operating range (see
chapter 12, “Technical Specifi cations”);
• large, rapid fl uctuations in room temperature;
• strong magnetic and/or radio frequency interference (avoid installing
near transmitting antennas);
• strong vibrations or knocks;
• presence of explosives or fl ammable gas mixtures;
• exposure to aggressive and polluting atmospheres (e.g. sulphur and
ammonia vapours, salt mist, fumes) that can cause corrosion and/or
oxidation;
• exposure to dust (formation of a corrosive patina with possible
oxidation and reduced insulation);
• exposure to water.
Positioning the controller inside the electrical panelInstall the controller inside an electrical panel in a position where it
cannot be reached and it is protected from knocks or impact. The
controller should be placed inside the panel in a position where it is
physically separated from power components (solenoids, contactors,
actuators, inverters, etc.) and their respective cables. The ideal solution
is to house these two circuits in two separate cabinets. Proximity to such
devices/cables may cause random malfunctions that are not immediately
evident. The panel casing must allow an adequate fl ow of cooling air.
Important:
• for safety reasons the controller should be installed inside an electrical
panel so that the only accessible parts are the display and the built-in
terminal keypad;
• install the controller so that the disconnect devices can be used safely
and without hindrance.
• when laying out the wiring, separate as much as possible the probe
cables, digital input cables and serial line cables from the power cables,
contactors, thermomagnetic devices, in order to avoid electromagnetic
interference;
• never run power cables and probe signal cables in the same conduits
(including the ones in the electrical panels);
• for control signals, use shielded cables with twisted wires. If the control
cables have to cross over power cables, the intersections should be as
close as possible to 90 degrees; under no circumstances should the
control cables be laid parallel to the power cables;
• keep the paths of the probe cables as short as possible and avoid
making spiral paths that enclose power devices;
• in case of malfunctions do not attempt to repair the device, but
contact a CAREL service centre.
Panel installation: c.pCOmini panel version
Procedure:
1. insert the gasket, with the smooth side facing the terminal;
2. place the terminal in the opening;
3. tighten the screws;
4. apply the frame, applying uniform pressure fi rstly on the 4 corners
(points D) and then on the middle points of the frame (points E), until
it clicks into place.
17
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Electrical installation
Important: before servicing the equipment, disconnect the controller
from the power mains by moving the system main switch to OFF.
Make sure the system is provided with a power disconnector conforming to
regulations. Use cable lugs that are suitable for the terminals used. Loosen each
screw and insert the cable lugs, then tighten the screws. There is no limit to the
number of wires that can be connected to each individual terminal. When
tightening the terminal screws apply a tightening torque no greater than 0.6
Nm. For information on the maximum allowable length of the connections
to the analogue/digital inputs and to the analogue outputs please refer to
the “Technical Specifi cations” (chapter 12). In environments subject to strong
disturbance use shielded cables with the braiding bonded to the earthing
conductor in the electrical panel. After making the connection, gently tug on
the cables to make sure they are suffi ciently tight.
Note: • secure the cables connected to the controller with clamps placed at
3cm from the connectors;
• if the power transformer secondary winding is earthed, make sure
the earth conductor is bonded to the conductor that goes to the
controller and is connected to terminal G0. This applies to all the
devices connected to the controller through a serial network.
Important: • using a supply voltage other than specifi ed can seriously damage the
system;
• connect the fuse close to the controller;
• the controller should only be installed, serviced and inspected
be qualifi ed personnel and in compliance with national and local
regulations;
• all the extra low voltage connections (24 Vac/Vdc or 28 to 36 Vdc
analogue and digital inputs, analogue outputs, serial bus connections,
power supplies) must have reinforced or double insulation from the
power mains;
• avoid touching or nearly touching the electronic components
mounted on the boards to avoid electrostatic discharges from the
operator to the components, which may cause considerable damage;
• do not press the screwdriver on the connectors with excessive force, to
avoid damaging the controller;
• using the device in any way other than specifi ed by the manufacturer
can compromise its protection;
• use only optional boards and connectors supplied by Carel.
4.3 Preliminary operationsInstalling the serial cardsIf the Fieldbus and BMS serial cards built into the c.pCO are insuffi cient
for the required application, you can add a Fieldbus serial port and a BMS
serial port, which are available as accessories (see chap.1).
To install them, proceed as follows:
• Locate the Fieldbus or BMS serial port.
• using a screwdriver, take off the cover;
• using a pair of nippers, cut out the plastic knock-out to create an
opening;
• plug the optional card into the edge connector, making sure it is fi rmly
secured and makes contact;
• put the cover back so that the serial card connector is aligned with
the opening;
• make the required electrical connections.
FieldBus card
BMS card
Fig. 4.c
Note: see the technical leafl ets for the cards being installed.
c.pCOe expansion board installationSee the technical leafl et +0500059IE.
Ultracap module installationSee the technical leafl ets +0500042IE and +0500041IE.
4.4 Electrical connections
Ethernet network
Connections:
• use CAT-5 STP shielded cables;
• always make the earth connection using the male spade near the
Ethernet connectors;
• the maximum length of an Ethernet connection is 100 m between
consecutive devices
J25 BMS2 J26 FBus2
J11 pLAN
c. pCO
MASTER
J25 BMS2 J26 FBus2
J11 pLAN
c.pCOJ25 BMS2 J26 FBus2
J11 pLAN
c.pCO
MASTER MASTERPC
max 100 m max 100 mmax 100 m
Fig. 4.d
RS485 network
To improve the controller immunity against electromagnetic interference,
the serial connection cable should be a shielded twisted pair cable,
2-wire or 3-wire depending on the isolation of the serial connection. The
following rule applies:
• if the serial port is isolated (functionally) from the power supply, a third
wire is required in the serial cable to act as a common reference for the
controllers. If the serial port is not optically isolated and the common
reference is already present, no third wire is required.
For the RS485 network, use a twisted pair cable with the specifi cations
shown in the table.
Master
device
HW Lmax(m) Wire/wire
capaci-
tance
(pF/m)
Resistor on
fi rst and last
devices
Max. no.
of slave
devices
on bus
Data
rate
(bit/s)
c.pCOminiFBUS
RS485
2/500 (not
shielded/
shielded
AWG 24)
< 90 120 Ω 64 19200
PC 120 Ω 207 38400
c.pCO Small...ExtralargeFBUS
RS4851000 < 90 120 Ω 64 19200
PC 1000 < 90 120 Ω 207 38400
Note: in case of a Master–Slave network the max. allowable length
is 1000 m. If the network is longer than 100 m, apply 120Ω, 1/4W
terminating resistors to the fi rst and last devices in the network.
Non-optically-isolated serial port
c.pCOmini: Fieldbus (J4) and BMS (J6).
c.pCO Small...Extralarge: serial ZERO - pLAN (J11), FieldBus 2 (J23 and
J26), and BMS2 if not optically isolated (on models with built-in ports that
are not optically isolated).
Case 1: multiple boards connected to a Master/Slave network powered
by the same transformer. Network length <100 m, terminating resistors
are not required (for example, multiple boards connected inside the
same electrical panel).
18
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
J3 Disp+Vterm L H
J4 FBus J5 CAN J3 Disp J4 FBus J6 BMS
+Vterm
J3 Disp J4 FBus J6 BMS
+Vterm
G G0 G G0 G G0
24 Vac
L N
230 Vac
24 Vac
L N
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
J25 BMS2J26 FBus2
J11 pLAN
c.pCO
G G0
Fig. 4.e
The procedure for earthing the shield is described in the corresponding paragraph.
Case 2: multiple boards connected to a Master/Slave network powered
by diff erent transformers (with G0 not earthed); this is a typical application
of multiple boards inside diff erent electrical panels. If the network is more
than 100 m long, the 120 Ω, ¼ W terminating resistor is required.
J3 Disp
+Vterm L H
J4 FBus J5 CAN J3 Disp J4 FBus J6 BMS
+Vterm
J3 Disp J4 FBus J6 BMS
+Vterm
G G0 G G0 G G0
230 Vac
24 Vac
L N230 Vac
24 Vac
L N230 Vac
24 Vac
L N
R = 120 Ω R = 120 Ω
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
230 Vac
24 Vac
L N230 Vac
24 Vac
L N230 Vac
24 Vac
L N
R = 120 Ω R = 120 Ω
Fig. 4.f
Important: the earth connection (if any) should be made only on
one point of the earth line (same earthing terminal for all controllers).
The procedure for earthing the shield is described in the corresponding paragraph.
Optically-isolated serial port
This is the case of serial ONE - BMS1, serial TWO - Fieldbus 1 and the built-
in ports serials THREE and FOUR on optically-isolated models. Regardless
of the type of power supply or earthing, use a 3-wire shielded cable
connected as shown in the fi gure. If the network is more than 100 m
long, the terminating resistor is required.
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
R = 120 Ω R = 120 Ω
Powersupply
Fig. 4.g
The procedure for earthing the shield is described in the corresponding paragraph.
Procedure for earthing the shield
The shield of the serial cable is earthed diff erently according to the
length, as shown in the fi gure (where A=FBus terminal, B=BMS terminal).
Case 1: distance between controllers less than 0.3 m: earth only one end
of the cable.
L < 300 mmL < 300 mm
A B B
Fig. 4.h
Case 2: distance between controllers greater than 0.3 m: two possibilities.
- earth one end with a bridge between the shields
L >300 mmL > 300 mm
A B B
Fig. 4.i
- earth both ends of the cable (no bridge between shields).
L >300 mmL > 300 mm
A B B
Fig. 4.j
19
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
4.5 Connecting the terminal
c.pCOmini
Use the accessory cable P/N S90CONN0S0, connected as shown in the
fi gure. The maximum distance allowed between controller and terminal
is 10 m.
od. S90CONN0S0BIANCO-WHITE/BLU = +VtermNERO-BLACK/ GIALLO-YELLOW = GNDROSSO/RED = -VERDE/GREEN = +
J3 Disp
+Vterm
BIANCO/WHITE
NERO/BLACK
ROSSO/RED
BLU
GIALLO/YELLOW
VERDE/GREEN
J3 Disp
+Vterm
Fig. 4.k
c.pCO Small...Extralarge
The controller and the terminal are connected to a pLAN network.
1: Connecting the terminal to one c.pCO controller When connecting the controller to the terminal, the following restrictions
should be kept in mind:
1. the overall length of the pLAN network should not exceed 500 m.
Consequently, if the terminal is installed in a remote position, the
length of the terminal cable must be included in the total length;
2. the unshielded telephone cable can be used for a max. length of
50 m. Beyond this length, use a 3-wire shielded cable (see the table
below);
3. for lengths greater than 200 m, the power supply for the terminal
must be provided separately;
4. no more than 3 terminals can be connected to the same c.pCO
controller. The terminals must be the same type (e.g. all pGD1).
One terminal is powered by the controller, and the other two by an
external power supply.
Important: • in domestic installations, standard EN55014 requires the connection
cable between the controller and the terminal to be shielded, with the
shield earthed at both ends;
• in industrial installations with length >10 m, the connection cable
between the controller and the terminal must be shielded and the
shield must be earthed.
Case A: 1 terminal.A.1: distance L < 50 m.The typical connection for one terminal (e.g. PGD1) is made using a 6-wire
telephone cable available from CAREL as an accessory (S90CONN00*).
The telephone connector provides both data transmission and the
power supply for the terminal.
To make the connection:
• plug the connector into terminal J10 until it clicks into place.
To remove the connector:
• press lightly on the plastic catch on the connector and pull it out.
L < 50 m
cavo telefonicotelephone cable
J10
J11 pLAN
Fig. 4.l
A.2: distance 50< L< 200 m.Lengths greater than 50 m require two TCONN6J000 cards connected
with a 4-wire shielded cable, as shown in the fi gure. The terminal is
powered by the controller.
J10
J11 pLAN
L < 200 m
0,8 m
MA
X
0,8 m
MA
X
cavo
telefonico
telepho
ne cab
le
Cavo schermato AWG20/222 twisted pair
6+ +TX
RXTXRX
-
+ -
-5 4 3 2 1 0
TCONN6J000
6 5 4 3 2 1 0 6 5 4 3 2 1 0
cavo
telefonico
telepho
ne cab
le
Fig. 4.m
Note: for information on the position of the jumpers on the
TCONN6J000 board, see instruction sheet +050002895.
A.3: distance 200< L< 500 m.The terminal must be powered by an external power supply. Connect
a 3-wire shielded cable to the pLAN connector (J11). Provide a separate
power supply for the TCONN6J000 card, as shown in the fi gure.
on/off alarm enter
menu I/O set prog.
?info
Graphic
G G0
U1
u2 U3
GND
+Vterm
GND
+5 VR
EFJ1 J24 J2
J10
J11 pLAN
L < 500 m
J14 and J15 on 2-3on TCONN6J000
AWG20/222 twisted pair
6 5 4 3 2 1 0
+
-
alimentatorepower supply
20...30 Vdc -150 mA
Fig. 4.n
Note: to reach the maximum network length, use a bus layout
with branches not exceeding 5 m.
Case B: 2 terminalsTwo terminals can be directly connected only on Small models. Other
sizes require the second terminal to be powered separately. On Medium/
Large/Extralarge controllers apply confi guration A.1, A.2 or A.3.
B.1: distance L < 50 m.Use 1 TCONN6J000 card, connected as shown in the fi gure.
cavo
telefonico
telepho
ne cab
le
J11 pLAN
TCONN6J000
6 5 4 3 2 1 0
on/off alarm enter
menu I/O set prog.
?info
Graphic
on/off alarm enter
menu I/O set prog.
?info
Graphic
0,8 m
MA
X
L < 50 mL < 50 m
Fig. 4.o
20
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
B.2 distance 50< L< 200 m.
Use 3 TCONN6J000 cards, connected as shown in the fi gure.
G G0
U1
u2 U3
GND
+Vterm
GND
+5 VR
EFJ1 J24 J2
J10
J11 pLAN
L < 200 m L < 200 m
6 5 4 3 2 1 0
cavo
telefonico
telepho
ne cab
le
6 5 4 3 2 1 0 6 5 4 3 2 1 0
on/off alarm enter
menu I/O set prog.
?info
Graphic
on/off alarm enter
menu I/O set prog.
?info
Graphic
0,8 m
MA
X
Fig. 4.p
B.3 distance 200< L< 500 m.If one of the terminals is connected at a distance >200 m, connect it
according to the diagram described in A.3. Connect the other terminal as
described in A.1 or A.2. If both terminals are close to a distance > 200 m,
connect them as shown in the diagram below:
on/off alarm enter
menu I/O set prog.
?info
Graphic
on/off alarm enter
menu I/O set prog.
?info
Graphic
G G0
U1
u2 U3
GND
+Vterm
GND
+5 VR
EFJ1 J24 J2
J10
J11 pLAN J31
CANL
CANH
GND
L < 500 m
J14 and J15 on 2-3on TCONN6J000
AWG20/221 twisted pair
6 5 4 3 2 1 0
+
-
alimentatorepower supply
20...30 Vdc -150 mA
Fig. 4.q
Case C: 3 terminals.For the fi rst 2 terminals refer to Case B. For the third terminal use one of
connections A.1, A.2 or A.3.
Important: • the 24 Vdc at +Vterm (J24) can be used only in alternative to connector
J10 to power an external terminal, with maximum current 1.5 W;
• in networks with a star layout, if the cable is longer than 5 m, connect
the terminal only to the fi rst or last c.pCO in the network (to avoid
branches).
The following table applies.
type of cable
MAX controller-terminal distance
(m)
power supply use TCONN6J000
card1 telephone 50 from the controller
(150 mA)
NO
2 shielded
AWG24
200 from the controller
(150 mA)
YES
3 shielded
AWG20/22
500 separate YES
2: Shared terminal connection in pLAN networkTo share a terminal between several c.pCO controllers, these can be
connected in a pLAN network, and the terminal connected to one of the
controllers in the network (see the fi gure below). The previous details on
the maximum length allowed between terminal and controller also apply
in this case.
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
J25 BMS2 J26 FBus2
J11 pLAN
c.pCO
G G0
230 Vac
24 Vac
L N230 Vac
24 Vac
L N230 Vac
24 Vac
L N
PGD
Fig. 4.r
It is possible use one terminal only, sharing it between controllers to
display the information relating to each (see the paragraph "Private and
shared terminal").
4.6 Input/output labelsc.pCO controllers are distinguished by size and provided with inputs
and outputs and power supplies for the active probes most suitable for
various applications.
The features that depend on the model are:
• maximum number and type of inputs/outputs;
• availability of built-in driver for expansion valves;
• type of interfaces
label Type of signalU... Universal inputs/outputs, can be confi gured via software as:
Analogue inputs:
- NTC PTC, PT500, PT1000 sensors
- PT100 sensors
- 0 to 1 Vdc or 0 to 10 Vdc signals
- 0/4 to 20 mA signals
- 0 to 5 V signals for ratiometric probes
Digital inputs (not optically-isolated):
- voltage-free contacts (not optically-isolated)
- fast digital inputs
Analogue outputs (not optically-isolated):
- 0 to 10 Vdc signals
- PWM signalsY... 0 to 10 Vdc analogue outputs, PWM outputsID... 24 Vac/ 24 Vdc digital inputID...H 230 Vac digital inputNO... Relay output, normally open contactNC... Relay output, normally closed contactC... Relay output, commonTx/Rx, GND Serial port
Ethernet port
Functional earth
Tab. 4.b
21
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
4.7 I/O table
c.pCO Controllers c.pCOe I/O expansion card
min
i (Ba
sic)
min
i (En
hanc
ed)
min
i (H
igh
End)
Smal
l
Med
ium
Larg
e
Extr
a La
rge
Built
-in
driv
er
Labe
l
In/O
ut
Type
Basi
c - c
.pCO
e
Labe
l
In/O
ut
Type
Universal
inputs/
outputs
NTC input 10 5 8 10 8 8 U In Universal I/O 10 U In Universal I/OPTC input 10 5 8 10 8 8 U In Universal I/O 10 U In Universal I/OPT500 input 10 5 8 10 8 8 U In Universal I/O 10 U In Universal I/OPT1000 input 10 5 8 10 8 8 U In Universal I/O 10 U In Universal I/OPT100 input max 5 max 2 max 3 max 4 max 3 max 3 U In Universal I/O max 5 U In Universal I/O0 to 1 Vdc / 0 to 10 Vdc input (powered
by controller)0
max
tot 5 max 5
max
tot 8 max 6
max
tot 1
0 max 6
max
tot 8 max 6
max
tot 8 max 6 U In Universal I/O 0 U In Universal I/O
0 to 1 Vdc / 0 to 10 Vdc input (powered
externally)
10
(Nota1)max 5 8 10 8 8 U In Universal I/O
10
(Note1)U In Universal I/O
0 to 20 / 4 to 20 mA input (powered
by controller)
max
tot 4
max 2
(Nota2)m
ax to
t 4 max 4
max
tot 7 max 6
max
tot 9 max 6
max
tot 7 max 6
max
tot 7 max 6 U In Universal I/O
max
tot 4
max 2
(Note2)U In Universal I/O
0 to 20 / 4 to 20 mA input (powered
externally)max 4 max 4 max 7 max 9 max 7 max 7 U In Universal I/O max 4 U In Universal I/O
0 to 5 V input for ratiometric probe
(+5Vref)max 2 max 5 max 6 max 6 max 6 max 6 U In Universal I/O 2 U In Universal I/O
Digital input w/ voltage-free contact 10 5 8 10 8 8 U In Universal I/O 10 U - Universal I/OFast digital inputs max 2 max 2 max 4 max 6 max 4 max 4 U In Universal I/O max 2 U - Universal I/O0 to 10 Vdc output, not optically-
isolatedmax 5 5 8 10 8 8 U Out Universal I/O max 5 U - Universal I/O
PWM output, not optically-isolated 10 5 8 10 8 8 U Out Universal I/O 10 U - Universal I/Omax tot 10 max tot 5 max tot 8 max tot 10 max tot 8 max tot 8 max tot 10
Digital
inputs
Optically-isolated 24 Vac/Vdc input 0 8 12 14 12 12 ID In Digital input 0 ID In Digital input24 Vac/Vdc or 230 Vac (50/60 Hz) input 0 - 2 4 2 2 ID In Digital input 0 ID In Digital inputVoltage-free contacts 0 2 - - - - - ID In Digital input 0 ID In Digital input
max tot 0 max tot 2 max tot 8 max tot 14 max tot 18 max tot 14 max tot 14 max tot 0
Analogue
outputs
0 to 10 Vdc output, optically-isolated 0 4 4 6 4 4 Y Out Analogue output 0 Y Out Analogue output0 to 10 Vdc output, not optically-
isolated0 2 0 0 0 0 0 Y1, Y2 Out Analogue output 0
Y1,
Y2Out Analogue output
PWM output, optically-isolated 0 2 2 2 2 2 Y3, Y4 Out Analogue output - - -
PWM output, not optically-isolated 0 2 0 0 0 0 0 Y1, Y2 Out Analogue output 0Y1,
Y2Out Analogue output
Output for single-pole stepper motor 0 1 0 0 0 0 0 J7 Out Analogue output 0 J7 Out Analogue outputOutput for two-pole stepper motor 0 0 0 0 0 1/2 1-3-2-4 Out Analogue output 0 - - -
max tot 0 max tot 2 max tot 4 max tot 4 max tot 6 max tot 4 max tot 6 max tot 0
Digital
outputs
NO/NC relay output 1 1 3 5 3 3 NO/NC Out Digital output 1NO/
NCOut Digital output
NO relay output 5 7 10 13 26 10 NO Out Digital output 5 NO Out Digital output24 V SSR output 2 1 2 3/4 2 2 NO Out Digital output 2 NO Out Digital output230 V SSR output 2 1 2 3/4 2 2 NO Out Digital output 2 NO Out Digital output
max tot 6 max tot 8 max tot 13 max tot 18 max tot 29 max tot 13 max tot 6
16 20 25 39 52 55 41 16 Total I/O
Note 1: CAREL probes, part numbers AS**** and DP****, can only be used with external power supply and not powered by c.pCOmini
Note 2: excluding CAREL probes part numbers AS**** and DP****
c.pCO Controllers c.pCOe I/O expansion card
min
i (Ba
sic)
min
i (En
hanc
ed)
min
i (H
igh
End)
Smal
l
Med
ium
Larg
e
Extr
a La
rge
Built
-in
driv
er
Labe
l
In/O
ut
Type
Basi
c - c
.pCO
e
Labe
l
In/O
ut
Type
Power to terminal 0 1 1 1 1 1 J10 0 --- Telephone conn. (pLAN) J101 0 0 0 0 0 J3 Disp 0 Display port J31 1 1 1 1 1 +Vterm 0 Add. power to terminal
Power to probes1 1 1 1 1 1 +VDC 1 Power to active probes1 1 1 1 1 1 +5 VREF 1 Power to ratiometric probes
Power to analogue outputs 0 1 1 1 1 1 VG, VG0 0Biult-in Fieldbus ports 0 1 1 1 1 2 2 1 J23/ J26, J4 (Mini) 0Accessory Fieldbus ports 0 1 1 1 1 1 Fbus card 0Biult-in BMS ports 0 1 0 1 1 1 1 1 J25, J6 (Mini) 1Accessory BMS ports 0 1 1 1 1 1 BMS card 0Host USB port
11 1 1 1 1
0Slave USB port 1 1 1 1 1Ethernet 0 0 1 1 1 1 1 1 0
22
C.pCO n° (03)
33,6°CTime 12:33date: 07.06.2013
54
1 2 3
6
87
Basic version
C.pCO n° (03)
33,6°CTime 12:33date: 07.06.2013
J6 BMS
1454
1 2 3
6
8
12
9
7
11
Enhanced version
C.pCO n° (03)
33,6°CTime 12:33date: 07.06.2013
)
°°CCC330606.20120133
54
1 2 3
6
8
12
9 13
14
7
11
High End version
+5
VR
EF
GN
D
+V
dc
J9
NO
3
C3
/4/5
NO
4
C3
/4/5
NO
5
J11
NO
6
NC
6
C6
J12
NO
1
C1
/2
NO
2
J10
G G0
V b
at
J1
U1
U2
U3
GN
D
U4
U5
U6
GN
D
U7
U8
U9
U1
0
GN
D
J2
J1 - G/G0: 24 V~ 50...60 Hz / 28...36 V 30 VA/12 W
J3 Disp.
+V
term
J7
54
1 2 3
6
87
Basic version
ID1
ID2
GN
D
Y1
Y2
GN
D
J8
+5
VR
EF
GN
D
+V
dc
J9J7
NO
3
C3
/4/5
NO
4
C3
/4/5
NO
5
J11
NO
6
NC
6
C6
J12
NO
1
C1
/2
NO
2
J10
G G0
V b
at
J1
U1
U2
U3
GN
D
U4
U5
U6
GN
D
U7
U8
U9
U1
0
GN
D
J2
J1 - G/G0: 24 V~ 50...60 Hz / 28...36 V 30 VA/12 W
J3 Disp.
+V
term
J4 FBus J6 BMS
14
12
9
11
Enhanced version
1 2 3
6
87
54
ID1
ID2
GN
D
Y1
Y2
GN
D
J8
+5
VR
EF
GN
D
+V
dc
J9J7
NO
3
C3
/4/5
NO
4
C3
/4/5
NO
5
J11
NO
6
NC
6
C6
J12
NO
1
C1
/2
NO
2
J10
G G0
V b
at
J1
U1
U2
U3
GN
D
U4
U5
U6
GN
D
U7
U8
U9
U1
0
GN
D
J2
J1 - G/G0: 24 V~ 50...60 Hz / 28...36 V 30 VA/12 W
J3 Disp.
+V
term
J4 FBus J5 CAN
L
1413
High End version
1 2 3
12
11
8
6
7
954
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
4.8 c.pCOmini e c.pCOe : connections terminals
Fig. 4.s
Key:
Ref. Description Ref. Description1 Power connector G(+), G0(-) 9 FieldBus connector
2 Vbat: terminal for external Ultracap module (accessory) 10 BMS connector
3 Universal inputs/outputs 11 Analogue outputs
4 +Vterm: terminal power supply 12 Digital inputs
5 Terminal connector 13 CANbus connector
6 Relay digital outputs 14 Ethernet port
7 Single-pole valve connector 15 Dip-Switches (only for c.pCOe)
8+5VREF: power supply for ratiometric probes
+VDC: power supply for active probes
23
12345678
9101112131415 with offset
no offset
19.2 K9.6 K38.4 K57.6 K
CARELModbus
ONOFF
Address Ext. ProtBaud
12345678
9101112131415 with offset
no offset
19.2 K9.6 K38.4 K57.6 K
CARELModbus
ONOFF
Address Ext. ProtBaud
1999.222 KKK99..66 KK33888.444 KKK55777.666 KKK
CCARERELMModbuodbus
PProottBBBaaauudd
ON ONFactory setting:address = not configured
extension = no offset
Baud Rate = 19.2 K
protocol = Modbus
Basic version
Address Ext Baud Prot
15 10
1 2 3
6
8
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Fig. 4.t
Description of connection terminals on c.pCO mini/c.pCOe
See the fi gures on the previous pages relating to c.pCO mini/c.pCOe
Ref. Term. Label Description
1J1-1 G Power supply at voltage A(*)J1-2 G0 Power supply reference
2 J1-3 Vbat Power supply from external Ultracap module
3
J2-1 U1 Universal input/output 1J2-2 U2 Universal input/output 2J2-3 U3 Universal input/output 3J2-4 GND Common for universal inputs/outputs 1, 2, 3J2-5 U4 Universal input/output 4J2-6 U5 Universal input/output 5J2-7 U6 Universal input/output 6J2-8 GND Common for universal inputs/outputs 4, 5, 6J2-9 U7 Universal input/output 7J2-10 U8 Universal input/output 8J2-11 U9 Universal input/output 9J2-12 U10 Universal input/output 10J2-13 GND Common for universal inputs/outputs 7, 8, 9, 10
4 J3-1 +Vterm Power supply for additional terminal
5J3-2 Tx-/Rx- Terminal RS485 port Tx-/Rx-J3-3 Tx+/Rx+ Terminal RS485 port Tx+/Rx+J3-4 GND Terminal RS485 port GND
6
J10-1 NO1 Normally open contact, relay 1J10-2 C1/2 Common for relay 1, 2J10-3 NO2 Normally open contact, relay 2J11-1 NO3 Normally open contact, relay 3J11-2 C3/4/5 Common for relay 3, 4, 5J11-3 NO4 Normally open contact, relay 4J11-4 C3/4/5 Common for relay 3, 4, 5J11-5 NO5 Normally open contact, relay 5J12-1 NO6 Normally open contact, relay 6J12-2 NC6 Normally closed contact, relay 6J12-3 C6 Common for relay 6
7 J7 - Single-pole valve connector
8J9-1 +5 VREF Power supply ratiometric probes 0 to 5 VJ9-2 GND Power supply commonJ9-3 +VDC Power to active probes
Ref. Term. Label Description
9J4-1 Tx-/Rx- FieldBus RS485 port Tx-/Rx-J4-2 Tx+/Rx+ FieldBus RS485 port Tx+/Rx+J4-3 GND FieldBus RS485 port GND
10J6-1 Tx-/Rx- BMS RS485 port Tx-/Rx-J6-2 Tx+/Rx+ BMS RS485 port Tx+/Rx+J6-3 GND BMS RS485 port GND
11J8-4 Y1 Analogue output 1, 0...10 VJ8-5 Y2 Analogue output 2, 0...10 VJ8-6 GND Common for analogue outputs 1, 2
12J8-1 ID1 Digital input 1J8-2 ID2 Digital input 2J8-3 GND Common for digital inputs 1, 2
13J5-1 TxL/RxL CANbus port TxL/RxLJ5-2 TxH/RxH CANbus port TxH/RxHJ5-3 GND CANbus port GND
(*) Voltage A: 24 Vac o 28...36 Vdc
24
SMALL
C1
NO
1
NO
2N
O3 C1
C4
NO
4N
O5
NO
6C
4
C7
NO
7
C7
NO
8C
8N
C8
G G0
U1
U2
U3
GN
D+
VDC
U4
GN
D
U5
GN
D
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1J1 J2 J3 J4 J5
J14
J10
J13J12 J15
drac SMBdrac suBdleiF
4 3 2 1
Tx/Rx
J11 pLANGND
J25 BMS2Tx/RxGND Tx/RxGND
J26 FBus2+
Vter
mG
ND
+5V
REF J24
+XXXXXXXXXXXX
26
25
18
17
12 1327 14Mac address
15
16
10 11
4 51 62 3 3 7 8
28
C1
NO
1
NO
2N
O3 C1
C4
NO
4N
O5
NO
6C
4
C7
NO
7
C7
NO
8C
8N
C8
G G0
U1
U2
U3
GN
D+
VDC
U4
GN
D
U5
GN
D
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1J1 J2 J3 J4 J5
J14
J10
J13J12 J15
drac SMBdrac suBdleiF
4 3 2 1
Tx/Rx
J11 pLANGND
J25 BMS2Tx/RxGND Tx/RxGND
J26 FBus2
+Vt
erm
GN
D+
5VRE
F J24
+XXXXXXXXXXXX N
O12
C12
NC
12
NO
13C
13N
C13C
9
NO
9N
O10
NO
11 C9
U6
U7
U8
GN
DID
9ID
10ID
11ID
12ID
C9
ID13
HID
13ID
C13
ID14
ID14
HJ7J8
J16 J17 J18
J6
8 9
MEDIUM
15
3
26
25
18
17
12 1327 14Mac address
15
16
10 11
4 51 62 3 3 7 8
28
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
4.1 c.pCO Small and Medium: connection terminals
Fig. 4.u
Key:Ref. Description Ref. Description1 Power conncetion G(+), G0(-) 12 Reserved
2+Vterm: power supply for additional terminal
+5 VREF power supply for ratiometric probes13 Ethernet port 1
3 Universal inputs/outputs 14 Ethernet port 2
4 +VDC: power supply for active probes 15 Relay digital outputs
5 Button for setting pLAN address, second display, LED 16 BMS2 port
6VG: power supply at voltage A(*) for opto-isolated analogue output
VG0: power to optically-isolated analogue output, 0 Vac/Vdc17 FieldBus2 port
7 Analogue outputs 18 Jumpers for selecting FieldBus/ BMS
8 ID: digital inputs for voltage A (*) 25 USB Host Port (Master)
9ID..: digital inputs for voltage A (*)
IDH..: digital inputs for voltage B (**)26 USB Device Port (Slave)
10 pLAN telephone connector for terminal 27 Faston for earth connection to Ethernet Port
11 pLAN plug-in connector 28 Display built-in and keypad
(*) Tensione A: 24 Vac o 28...36 Vdc; (**) Tensione B: 230 Vac - 50/60 Hz.
25
C1
NO
1
NO
2N
O3 C1
C4
NO
4N
O5
NO
6C
4
C7
NO
7
C7
NO
8C
8N
C8
G G0
U1
U2
U3
GN
D+
VDC
U4
GN
D
U5
GN
D
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1J1 J2 J3 J4 J5
J14
J10
J13J12 J15
drac SMBdrac suBdleiF
4 3 2 1
Tx/Rx
J11 pLANGND
J25 BMS2Tx/Rx GND Tx/Rx GND
J26 FBus2
+Vt
erm
GN
D+
5VRE
F J24
+XXXXXXXXXXXX
U6
U7
U8
GN
D
J20
J21 J22
J16 J17 J18
J6
J19
NO
14C
14N
C14
NO
15C
15N
C15
C16
NO
16
NO
17N
O18
C16
ID15
HID
15ID
C15
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC
17
U9
GN
DU
10G
ND
J23 FBus2
3 8 9
1915
9 3 8
LARGE
C9N
O9
NO
10
NO
11 C9
NO
12C
12
NC
12
NO
13C
13N
C13
ID9
ID10
ID11
ID12
IDC
9
J7
ID13
H
ID13
IDC
13ID
14ID
14H
J8
Tx/Rx GND
7
15
26
25
12 1327 14Mac address
15
16
10 11
4 51 62 3 3 7 8
28
1817
EXTRALARGE
C25
NO
25N
O26
NO
27N
O28
NO
29
C25
J20
C21
NO
21N
O22
NO
23N
O24
C21
15
C17
NO
17N
O18
NO
19N
O20
C17
J19
C1
NO
1
NO
2N
O3 C1
C4
NO
4N
O5
NO
6C
4
C7
NO
7
C7
NO
8C
8N
C8
G G0
U1
U2
U3
GN
D+
VDC
U4
GN
D
U5
GN
D
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1J1 J2 J3 J4 J5
J14
J10
J13J12 J15
drac SMBdrac suBdleiF
4 3 2 1
Tx/Rx
J11 pLANGND
J25 BMS2Tx/Rx GND Tx/Rx GND
J26 FBus2
+Vt
erm
GN
D+
5VRE
F J24
+XXXXXXXXXXXX
C14
NO
14
NO
15N
O16
C14
U6
U7
U8
GN
D
J21 J22
J16 J17 J18
J6
J23 FBus2
3 8 9
1915
C9N
O9
NO
10
NO
11 C9
NO
12C
12
NC
12
NO
13C
13N
C13
ID9
ID10
ID11
ID12
IDC
9
J7
ID13
H
ID13
IDC
13ID
14ID
14H
J8
Tx/Rx GND
26
25
12 1327 14Mac address
15 15
16
10 11
4 51 62 3 3 7 8
28
1817
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
4.9 c.pCO Large and Extralarge: connection terminals
Fig. 4.v
Key:Ref. Description Ref. Description
1 Power connector G(+), G0(-) 13 Ethernet port 1
2+Vterm: power supply for additional terminal
+5 VREF power supply for ratiometric probes14 Ethernet port 2
3 Universal inputs/outputs 15 Relay digital outputs
4 +VDC: power supply for active probes 16 BMS2 port
5 Button for setting pLAN address, second display, LED 17 FieldBus2 port
6VG: power supply at voltage A(*) for opto-isolated analogue output
VG0: power to optically-isolated analogue output, 0 Vac/Vdc18 Jumpers for selecting FieldBus/ BMS
7 Analogue outputs 19 FieldBus2 port
8 ID: digital inputs for voltage A (*) 25 USB Host Port (Master)
9ID..: digital inputs for voltage A (*)
IDH..: digital inputs for voltage B (**)26 USB Device Port (Slave)
10 pLAN telephone connector for terminal/downloading application 27 Faston for earth connection to Ethernet Port
11 pLAN plug-in connector 28 Display built-in and keypad
12 Reserved
(*) Voltage A: 24 Vac or 28-36 Vdc; (**) Voltage B: 230 Vac - 50/60 Hz.
26
C1
NO
1
NO
2N
O3 C1
C4
NO
4N
O5
NO
6C
4
C7
NO
7
C7
NO
8C
8N
C8
G G0
U1
U2
U3
GN
D+
VDC
U4
GN
D
U5
GN
D
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1J1 J2 J3 J4 J5
J14
J10
J13J12 J15
drac SMBdrac suBdleiF
4 3 2 1
Tx/Rx
J11 pLANGND
J25 BMS2Tx/Rx GND Tx/Rx GND
J26 FBus2
+Vt
erm
GN
D+
5VRE
F J24
+XXXXXXXXXXXX
A B C D
NO
12C
12N
C12
NO
13C
13N
C13C9
NO
9N
O10
NO
11 C9
U6
U7
U8
GN
D
J8
J16 J17 J18
J6
3 8 9
22 24
20 21
J27
1 3 2 4
J28
1 3 2 4
driver
VBA
TG
0G
J30
23
GN
D
VREF
S1 S2 S3 S4 DI1
DI2
J29
BUILT - IN DRIVER
ID13
HID
13ID
C3
ID14
ID14
H
ID9
ID10
ID11
ID12
IDC
9J7
15
26
25
18
17
12 1327 14Mac address
15
16
10 11
4 51 62 3 3 7 8
28
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
4.2 c.pCO built-in driver: connection terminalsTwo models of c.pCO are available with one or two built-in electronic expansion valve drivers.
Fig. 4.w
Key:Ref. Description Ref. Description
1 Power connctor G(+), G0(-) 15 Relay digital outputs
2+Vterm: power supply for additional terminal
+5 VREF power supply for ratiometric probes16 BMS2 port
3 Universal inputs/outputs 17 FieldBus2 port
4 +VDC: power supply for active probes 18 Jumpers for selecting FieldBus/ BMS
5 Button for setting pLAN address, second display, LED 20 Electronic valve A connector
6VG: power supply at voltage A(*) for opto-isolated analogue output
VG0: power to optically-isolated analogue output, 0 Vac/Vdc21 Electronic valve B connector
7 Analogue outputs 22 Connector for external Ultracap module (accessory)
8 ID: digital inputs for voltage A (*) 23 Valve driver analogue and digital inputs
9ID..: digital inputs for voltage A (*)
IDH..: digital inputs for voltage B (**)24 Valve status indicator LED
10 pLAN telephone connector for terminal 25 USB Host Port (Master)
11 pLAN plug-in connector 26 USB Device Port (Slave)
12 Reserved 27 Faston for earth connection to Ethernet Port
13 Ethernet port 1 28 Display built-in and keypad
14 Ethernet port 2
(*) Voltage A: 24 Vac or 28-36 Vdc; (**) Voltage B: 230 Vac - 50/60 Hz.
Description of connection terminals on c.pCO Small... Extralarge
Ref. Term. Label Description
1J1-1 G Power supply at voltage A(*)J1-2 G0 Power supply reference
2J24-1 +Vterm Additional power supply terminalJ24-2 GND Power supply commonJ24-3 +5 VREF Power supply ratiometric probes 0 to 5 V
3
J2-1 U1 Universal input/output 1J2-2 U2 Universal input/output 2J2-3 U3 Universal input/output 3J2-4 GND Common for universal inputs/outputs 1, 2, 3
3
J3-1 U4 Universal input/output 4J3-2 GND Common for universal input/output 4J3-3 U5 Universal input/output 5J3-4 GND Common for universal input/output 5
3
J6-1 U6 Universal input/output 6J6-2 U7 Universal input/output 7J6-3 U8 Universal input/output 8J6-4 GND Common for universal inputs/outputs 6, 7, 8
Ref. Term. Label Description
3
J20-3 U9 Universal input/output 9J20-4 GND Common for universal input/output 9J20-5 U10 Universal input/output 10J20-6 GND Common for universal input/output 10
4 J2-5 +VDC Power to active probes
5 Button for setting pLAN address, secondary display, LED
6
J4-1 VGPower to optically-isolated analogue output,
voltage A(*)
J4-2 VG0Power to optically-isolated analogue output, 0
Vac/Vdc
7
J4-3 Y1 Analogue output 1, 0 to 10 V
J4-4 Y2 Analogue output 2, 0 to 10 V
J4-5 Y3 Analogue output 3, 0 to 10 V
J4-6 Y4 Analogue output 4, 0 to 10 V
7J20-1 Y5 Analogue output 5, 0 to 10 V
J20-2 Y6 Analogue output 6, 0 to 10 V
27
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Ref. Term. Label Description
8
J5-1 ID1 Digital input 1 at voltage A(*)
J5-2 ID2 Digital input 2 at voltage A(*)J5-3 ID3 Digital input 3 at voltage A(*)J5-4 ID4 Digital input 4 at voltage A(*)J5-5 ID5 Digital input 5 at voltage A(*)J5-6 ID6 Digital input 6 at voltage A(*)J5-7 ID7 Digital input 7 at voltage A(*)J5-8 ID8 Digital input 8 at voltage A(*)
J5-9 IDC1Common for digital inputs from 1 to 8 (negative
pole for DC power supply)
8
J7-1 ID9 Digital input 9 at voltage A(*)J7-2 ID10 Digital input 10 at voltage A(*)J7-3 ID11 Digital input 11 at voltage A(*)J7-4 ID12 Digital input 12 at voltage A(*)
J7-5 IDC9Common for digital inputs from 9 to 12 (negative
pole for DC power supply
8
J20-7 ID17 Digital input 17 at voltage A(*)
J20-8 ID18 Digital input 18 at voltage A(*)
J20-9 IDC17Common for digital inputs 17 and 18 (negative
pole for DC power supply
9
J8-1 ID13H Digital input 13 at voltage B(**)J8-2 ID13 Digital input 13 at voltage A(*)
J8-3 IDC13Common for digital inputs 13 and 14 (negative
pole for DC power supply)J8-4 ID14 Digital input 14 at voltage A(*)J8-5 ID14H Digital input 14 at voltage B(**)
9
J19-1 ID15H Digital input 15 at voltage B(**)J19-2 ID15 Digital input 15 at voltage A(*)
J19-3 IDC15Common for digital inputs 15 and 16 (negative
pole for DC power supply)J19-4 ID16 Digital input 16 at voltage A(*)J19-5 ID16H Digital input 16 at voltage B(**)
10 J10 - Connector for telephone cable pLAN
11J11-1 Tx-/Rx- pLAN RS485 port Tx-/Rx-J11-2 Tx+/Rx+ pLAN RS485 port Tx+/Rx+J11-3 GND pLAN RS485 port GND
12 - - Reserved13 - - Ethernet port 114 - - Ethernet port 2
15
J12-1 C1 Common for relays 1, 2, 3J12-2 NO1 Normally open contact, relay 1J12-3 NO2 Normally open contact, relay 2J12-4 NO3 Normally open contact, relay 3J12-5 C1 Common for relay 1, 2, 3J13-1 C4 Common for relay 4, 5, 6J13-2 NO4 Normally open contact, relay 4J13-3 NO5 Normally open contact, relay 5J13-4 NO6 Normally open contact, relay 6J13-5 C4 Common for relay 4, 5, 6J14-1 C7 Common for relay 7J14-2 NO7 Normally open contact, relay 7J14-3 C7 Common for relay 7J15-1 NO8 Normally open contact, relay 8J15-2 C8 Common for relay 8J15-3 NC8 Normally closed contact 8J16-1 C9 Common for relay 9, 10, 11J16-2 NO9 Normally open contact, relay 9J16-3 NO10 Normally open contact, relay 10J16-4 NO11 Normally open contact, relay 11J16-5 C9 Common for relay 9, 10, 11J17-1 NO12 Normally open contact, relay 12J17-2 C12 Common for relay 12J17-3 NC12 Normally closed contact 12J18-1 NO13 Normally open contact, relay 13J18-2 C13 Common for relay 13J18-3 NC13 Normally closed contact 13J21-1 NO14 Normally open contact, relay 14J21-2 C14 Common for relay 14J21-3 NC14 Normally closed contact 14J21-4 NO15 Normally open contact, relay 15J21-5 C15 Common for relay 15J21-6 NC15 Normally closed contact 15J22-1 C16 Common for relay 16, 17, 18J22-2 NO16 Normally open contact, relay 16J22-3 NO17 Normally open contact, relay 17J22-4 NO18 Normally closed contact 18J22-5 C16 Common for relay 16, 17, 18J21-1 C14 Common for relay 14, 15, 16J21-2 NO14 Normally open contact, relay 14J21-3 NO15 Normally open contact, relay 15J21-4 NO16 Normally open contact, relay 16J21-5 C14 Common for relay 14, 15, 16
Ref. Term. Label Description
15
J22-1 C17 Common for relay 17, 18, 19, 20J22-2 NO17 Normally open contact, relay 17J22-3 NO18 Normally open contact, relay 18J22-4 NO19 Normally open contact, relay 19J22-5 NO20 Normally open contact, relay 20J22-6 C17 Common for relay 17, 18, 19, 20J19-1 C21 Common for relay 21, 22, 23, 24J19-2 NO21 Normally open contact, relay 21J19-3 NO22 Normally open contact, relay 22J19-4 NO23 Normally open contact, relay 23J19-5 NO24 Normally open contact, relay 24J19-6 C21 Common for relay 21, 22, 23, 24J20-1 C25 Common for relay 25, 26, 27, 28, 29J20-2 NO25 Normally open contact, relay 25J20-3 NO26 Normally open contact, relay 26J20-4 NO27 Normally open contact, relay 27J20-5 NO28 Normally open contact, relay 28J20-6 NO29 Normally open contact, relay 29J20-7 C25 Common for relay 25, 26, 27, 28, 29
16J25-1 Tx-/Rx- Tx-/Rx- RS485 BMS2 portJ25-2 Tx+/Rx+ Tx+/Rx+ RS485 BMS2 portJ25-3 GND GND RS485 BMS2 port
17J26-1 Tx-/Rx- Tx-/Rx- RS485 Fieldbus 2 portJ26-2 Tx+/Rx+ Tx+/Rx+ RS485 Fieldbus 2 port
18 Port J26 confi guration microswitches
19J23-1 Tx-/Rx- Tx-/Rx- Fieldbus 2 RS485 portJ23-2 Tx+/Rx+ Tx+/Rx+ Fieldbus 2 RS485 portJ23-3 GND GND RS485 port network Fieldbus 2
For pCO5+ built-in driver only:
20
J27-1 1Electronic expansion valve 1 control (see par.
“Electronic valve connection”).
J27-2 3J27-3 2J27-4 4
21
J28-1 1Electronic expansion valve 2 control (see par.
“Electronic valve connection”).
J28-2 3J28-3 2J28-4 4
22J30-1 VBAT
Power supply from external Ultracap moduleJ30-2 G0J30-3 G
23
J29-1 GND Common probe power supplyJ29-2 VREF Probe driver power supplyJ29-3 S1 Probe 1J29-4 S2 Probe 2J29-5 S3 Probe 3J29-6 S4 Probe 4 J29-7 DI1 Digital input 1J29-8 DI2 Digital input 2
24A, B Valve A status LEDC, D Valve B status LED
Tab. 4.c
(*): voltage A: 24 Vac or 28...36 Vdc;
(**): voltage B: 230 Vac - 50/60 Hz.
: Large model; : Extralarge model
28
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
5. INPUT/OUTPUT CONNECTIONS
5.1 Power supplyThe fi gure below shows the power supply connection diagram. Use
a class II safety isolation transformer with short-circuit and overload
protection. See the Technical Specifi cations table for information on the
size of the transformer required by each model (see chap. 13).
24 Vac
230 Vac
2.5 A T
G G0
J1
28...36 Vdc
2.5 A T
G G0
J1
-+
AC DC
Fig. 5.a
Important:• power the c.pCO built-in driver with AC voltage only, with the
transformer secondary winding earthed;• if the Ethernet connection is featured and used, the transformer
secondary must be earthed;
• using a supply voltage other than specifi ed can seriously damage the
controller;
• if the transformer secondary is earthed, make sure that the earth
conductor is connected to terminal G0. This applies to all the devices
connected to the c.pCO through a serial network;
• if more than one c.pCO board is connected to a pLAN network, make
sure that the G and G0 references are observed (G0 must be maintained
for all controllers);
• the power supply to the controller(s) and the terminal(s) should be
kept separate from the power supply to the other electrical devices
(contactors and other electromechanical components) inside the
electrical panel.
Note: • when the controller is powered, the yellow LED lights up;
• refer to the diagrams in par. 4.4 in case of controllers connected to a
pLAN network and installed in the same electrical panel or in separate
panels.
5.2 Universal inputs/outputsUniversal inputs/outputs are distinguished by the letter U...
They can be confi gured from the application program for many diff erent
uses, such as the following:
• passive temperature probes: NTC, PTC, PT100, PT500, PT1000;
• active pressure/temperature/humidity probes;
• ratiometric pressure probes;
• current inputs, 0 to 20 mA or 4 to 20 mA;
• voltage inputs, 0 to 1 Vdc or 0 to 10 Vdc;
• voltage-free contact digital inputs and fast digital inputs;
• analogue outputs, 0 to 10 Vdc;
• PWM outputs.
Important: • the universal inputs/outputs must be pre-confi gured to handle their
respective signals from the application program;
• the universal inputs/outputs cannot be used as digital outputs.
Max. number of connectable analogue inputsThe maximum number of analogue inputs that can be connected to the
universal inputs/outputs depends on the type used.
Maximum number of inputs connectable to universal inputs/outputs Type of signal c.pCO
mini -
c.pCOe
Small Medium/ Built-in
driver/ Extralarge
Large
Ana
logu
e in
puts
- NTC/PTC/
PT500/PT1000
probes
10 5 8 10
- PT100 probes max 5 2 3 (2 on U1...U5, 1
on U6...U8)
4 (2 on U1...U5, 1 on
U6...U8, 1 on U9...
U10)- 0 to 1 Vdc/0
to 10 Vdc
signals from
probes po-
wered by the
controller
0
ma
x to
t 5
5
ma
x to
t 8
6
ma
x to
t 1
0
max 6
- 0 to 1 Vdc/0
to 10 Vdc si-
gnals powered
externally
10 5 8 10
- 0 to 20 mA
/4 to 20 mA
inputs from
probes po-
wered by the
controller
ma
x to
t 4
2
ma
x to
t 4
4
ma
x to
t 7
6:
(max 4 on U1...
U5,
3 on U6...U8)
ma
x to
t 9
6:
(max 4 on U1...
U5,
3 on U6...U8,
2 on U9...U10)
- 0 to 20 mA
/ 4 to 20 mA
inputs from
probes powe-
red externally
4 4 7:
(max 4 on U1...
U5,
3 on U6...U8)
9:
(max 4 on U1...
U5,
3 on U6...U8,
2 on U9...U10)- 0 to 5 V
signals from
ratiometric
probes po-
wered by the
controller
max 2 max 5 max 6 max 6
Tab. 5.a
Note: the table shows the maximum number of inputs that can be
connected. For example, it is possible to connect to a Small size controller
a maximum of fi ve 0 to 1Vdc inputs related to probes powered by the
controller, and a a maximum of fi ve 0 to 1 Vdc inputs related to probes
powered externally. In any case, maximum number of 0 to 1Vdc inputs
must be 5.
Remote connection of analogue inputs
The table below shows the required cable sizes to be used for the remote
connection of the analogue inputs.
Type of input Cross section for lengths <50 m (mm2)
Cross section for lengths <100 m (mm2)
NTC 0,5 1,0
PT1000 0,75 1,5
I (current) 0,25 0,5
V (current) 0,25 0,5
Tab. 5.b
Important: • if the controller is installed in an industrial environment (standard
EN 61000-6-2) the connections must be less than 10 m long; do not
exceed this length to avoid measurement errors.
• to avoid electromagnetic interference, keep the probe and digital
input cables separate from the power cables as much as possible (at
least 3 cm). Never run power cables and probe signal cables in the
same conduits (including the ones in the electrical panels).
29
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Connecting NTC, PTC temperature probes
For information on the maximum number of probes that can be
connected see the table at the beginning of this paragraph. For details
on the operating range see the Technical Specifi cations table (cap. 12).G G0 U1 U2 U3 G
ND
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
J1 J24 J2 J3 J4 J5
Fie ldBus card BMS card
U1
U2
U3
GN
D+V
DC
U4
GN
D U5
GN
D
1
2 3
4
Fig. 5.b
KeyController terminals NTC probe
1 2 3 4
GND Wire 1
U1 Wire 2
GND Wire 1
U2 Wire 2
GND Wire 1
U4 Wire 2
GND Wire 1
U5 Wire 2
Connecting PT500/PT1000 temperature probes
For information on the maximum number of probes that can be
connected see the table at the beginning of this paragraph. For
details on the operating range see the Technical Specifi cations table
(cap. 12).
Important: • to ensure correct measurements from the probe each wire must be
connected to only one terminal.
• the two probe wires have no polarity.
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
J1 J24 J2 J3 J4 J5
Fie ldBus card BMS cardinput: 24 V 50...60 Hz / 28...36 Vmax. power: 45 VA/20 W
U1
U2
U3
GN
D+V
DC
U4
GN
D U5
GN
D
1
2
Fig. 5.c
KeyController terminals PT500/PT1000 probe
1 2
GND Wire 1
U4 Wire 2
GND Wire 1
U5 Wire 2
Connecting PT100 temperature probes
For information on the maximum number of probes that can be
connected see the table at the beginning of this paragraph. For details on
the operating range see the Technical Specifi cations table (see chap. 12).
The probe has three wires: connect one to GND and the other two to two
separate but adjacent universal inputs on the same controller (e.g. U1, U2,
GND, or U4, U5, GND).
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
J1 J24 J2 J3 J4 J5
Fie ldBus card BMS card
U1
U2
U3
GN
D+V
DC
U4
GN
D U5
GN
D
1
2 3
4
Fig. 5.dKeyController terminals PT100 probe
1 2
U1 Wire 1 (red)
U2 Wire 2 (red)
GND Wire 3 (white)
U4 Wire 1 (red)
U5 Wire 2 (red)
GND Wire 3 (white)
Connecting active temperature and humidity probes
For information on the maximum number of probes that can be connected
see the table at the beginning of this paragraph. The number depends on
the power supply used. The distinction is between probes powered by the
controller (terminal +VDC) and probes powered by an external source, and
also between active probes with voltage or current outputs. For details
on the operating range see the data sheets supplied with the probes. The
controller can be connected to all the CAREL DP* series active temperature
and humidity probes confi gured for 0 to 1 V or 4 to 20 mA.
Note: in c.pCOmini models it is not possible to manage 0 to 1 Vdc
or 0 to 10 Vdc signals coming from probes powered directy by the
controller.
Important: for temperature probes use the 4 to 20 mA or NTC
confi guration, cause 0 to 1 Vdc signal is limited to the 0 to 1 V range and
is therefore not always compatible with the standard 10 mV/°C signal of
CAREL probes (at temperatures below 0 °C or above 100 °C a probe alarm
may be activated).
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
J1 J24 J2 J3 J4 J5
Fie ldBus card BMS card
U1
U2
U3
GN
D+V
DC
Mout T
+ (G)
out H
Fig. 5.e
KeyController terminals Probe terminals Description
GND M Reference
+VDC +(G) Probe power supply
U1 outH Humidity probe output
U2 outT Temperature probe output
30
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Connecting current-output pressure probes
For information on the maximum number of probes that can be connected
see the table at the beginning of this paragraph. For details on the operating
range see the data sheets supplied with the probes. The controller can
be connected to all CAREL SPK* series active pressure probes or any
commercially available pressure probes with 0 to 20 mA or 4 to 20 mA signals.G G0 U1 U2 U3 G
ND
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
J1 J24 J2 J3 J4
Fie ldBus card BMS card
U1
U2
U3
GN
D+V
DC
U4
GN
D U5
GN
D
1
12
2 1
2
Fig. 5.f
KeyController
terminals
Current-output pressure probe
1 2
+VDC Wire 1 power brown Wire 1 power brown
U1 Wire 2 Signal white -
U2 Wire 2 Signal white
Connecting 0 to 5 V ratiometric pressure probes
For information on the maximum number of probes that can be
connected see the table at the beginning of this paragraph. For details
on the operating range see the probe data sheets. The controller can
be connected to all CAREL SPKT series active pressure probes or any
commercially available pressure probes with 0 to 5 V ratiometric signals.
Important: • ratiometric probes are powered by the controller via terminal +5 VREF;
• ratiometric probes cannot be powered by an external source.
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
J1 J24 J2 J3 J4
Fie ldBus card BMS card
U1
U2
U3
GN
D
GN
D
+5 V
REF
+VD
C
Fig. 5.g
KeyController terminals Description Wire colour
+5 Vref Power black
GND Power reference green
U1 Signal white
Connecting active probes with 0 to 10 V output
For information on the maximum number of probes that can be
connected see the table at the beginning of this paragraph. For details
on the operating range see the data sheets supplied with the probes.
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
J1 J24 J2 J3 J4
Fie ldBus card BMS card
U1
U2
U3
GN
D+V
DC
Mout T
+ (G)
out H
Fig. 5.h
KeyController terminals Active probes with 0 to 10 V output
GND Reference
+VDC Power
U1 Signal 1
U2 Signal 2
Max. number of connectable digital inputs
The controller allows the universal inputs/outputs to be confi gured as
non-optically isolated, voltage-free digital inputs. In any case, the inputs
must be connected to a voltage-free contact.
Maximum number of dig. inputs connectable to universal inputs/outputs
Type of signal
c.pCO
mini SmallMedium/ Built-in
driver/ ExtralargeLarge
Digital
inputs
(not opto-
isolated)
- volt-free
contacts10 5 8 10
- fast
inputsmax 2 max 2
4
(max 2 on U1...U5,
max 2 on U6..U8)
6
(max 2 on U1...U5,
max 2 on U6...U8,
2 on U9...U10)
Tab. 5.c
Important: the maximum current allowed on the digital input is 10
mA. Therefore the rating of the external contact must be at least 10 mA.
Connecting ON/OFF inputs
There is no particular restriction on the maximum number of inputs that
can be connected. For details on the operating range see the Technical
Specifi cations table (see chap. 12).
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
J1 J24 J2 J3 J4 J5
Fie ldBus card BMS card
U4
U5
GN
D
GN
D
Fig. 5.i
KeyController terminals Description
U4Digital input 1
GND
U5Digital input 2
GND
Connecting fast digital inputs
Important: the wires connecting the fast digital inputs/counters
must be shielded to avoid causing electromagnetic interference with the
probe cables.
G G0 U1 u2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
J1 J24 J2 J3
Fie ldBus card
U4 GND
U5 GND
J3
Externalimpulsegenerator
Fig. 5.j
31
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
The fast digital input can be used as a frequency meter. The count is
performed on the rising edge of the pulse. The pulse generator device
will have one digital output with transistor optocoupler, which will be
connected to the input as shown in the fi gure. For details on the input
signal see the Technical Specifi cations table (see chap. 12).
Note: the application program shows the frequency values using
specifi c variables. If the inputs are confi gured as counters, the counter is
reset by the application program.
Example:
t
t
input
count
Fig. 5.k
Note: in the case of fans with current output and high series
resistance, the reading of the pulses may depend on the current. The
current value can be confi gured in the c.design I/O Editor.
Connecting non-optically-isolated analogue outputs
There is no particular restriction on the number of outputs that can
be connected. For details on the output signal see the Technical
Specifi cations table (see chap. 12).
Example: analogue/PWM output connection diagram.
U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
J24 J2 J3 J4
ID1
Vout
Vout
Fig. 5.l
KeyController terminals Description
U1Analogue output 1
GND
U2Analogue output 2
GND
U3Analogue output 3
GND
Note: the analogue outputs cannot be connected in parallel.
5.3 Digital inputsThe controller features digital inputs for connecting safety devices, alarms,
device status indicators and remote switches. See the table of technical
specifi cations for the maximum cable length cables (see chap. 12).
c.pCOmini
The digital inputs are not optically-isolated and have voltage-free
contacts. The following fi gure shows how to connect the digital inputs:
U1 U2 U3 GND
U4 U5 U6 GND
U7 U8 U9 U10
GNDJ1
G G0 Vbat
+5VR
EFGN
D+V
DCJ9
Y1GND
ID2
ID1
Y2 GNDJ8J7
J2
Fig. 5.m
c.pCO Small...Extralarge
These inputs are all optically isolated from the other terminals. They can
work at 24 Vac (+10/-15%) or 28 to 36 Vdc (-20/+10%) (indicated as ID*),
and some at 230 Vac (indicated as IDH*), see as reference fi gure below.
Note:• if the control voltage is drawn in parallel with a coil, install a dedicated
RC fi lter in parallel with the coil (typical ratings are 100 Ω, 0.5 μF, 630 V);
• if the digital inputs are connected to safety systems (alarms), the
presence of voltage across the contact should be taken as the normal
operating condition, while no voltage represents an alarm situation.
This will ensure that any interruption (or disconnection) of the input
will also be signalled;
• do not connect the neutral in place of an open digital input;
• always interrupt the phase.
Important: • to avoid electromagnetic interference, keep the probe and digital
input cables separate from the power cables as much as possible (at
least 3 cm). Never run power cables and probe signal cables in the
same conduits (including the ones in the electrical panels.
24 Vac digital inputs (c.pCO Small... Extralarge only)
Digital inputs ID... can be controlled at 24 Vac.
Note: • the digital inputs are only functionally isolated from the rest of the
controller;
• to keep the digital inputs optically isolated a separate power supply is
needed for each input;
• the digital inputs can be powered at a diff erent voltage from the rest
of the controller.
Cable cross-section
For remote connections to the digital inputs (length <50 m), use cables
with a cross-section = 0.25 (mm2)
Important: If the controller is installed in an industrial environment
(standard EN 61000-6-2) the connections must be less than 30 m long. Do
not exceed this length to avoid measurement errors.
32
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Example of connection diagram (LARGE model):
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1
U6
U7
U8
GND
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC
13
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J20
J6
J19
ID15
H
ID15
IDC
15
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC
17
U9
GN
D
U10
GN
DF ie ldBus card B M S card
GG0
24 Vac
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC
13
ID14
ID14
H
Fig. 5.n
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7
J8
J20
J6
J19
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
230 VacL
N
-
+24 Vdc
Fig. 5.o
24 Vdc digital inputs
The ID... digital inputs can be controlled at 24 Vdc.
Example of connection diagram (LARGE model):
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7
J8
J20
J6
J19
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
input: 24 V 50...60 Hz / 28...36 Vmax. power: 45 VA/20 W
-
+24 Vdc
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC13
ID14
ID14
H
Fig. 5.p
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J20
J6
J19
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
-
+24 Vdc
Fig. 5.q
33
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
230 Vac digital inputs (c.pCO Medium...Extralarge only)
Medium and Extralarge models feature one group of 230 Vac inputs
(terminal J8), while Large models have two groups (on terminals J8 and
J19). Each group consists of two digital inputs that can be powered at 230
Vac, indicated as IDH*, and two inputs that can be powered at 24 Vac/Vdc,
indicated as ID*. The two groups of 230 Vac inputs have double insulation
between each other and between them and the controller. The digital
inputs connected may be the 24 Vac/dc inputs from one group and the
230 Vac inputs from the other. The two inputs of each group have the
same common pole. Functional insulation is provided. In each group, the digital inputs must be powered at the same voltage (24 Vac, 28 to 36 Vdc or 230 Vac) in order to avoid dangerous short-circuits and/or the risk of powering lower-voltage circuits at 230 Vac
Note:
• the range of uncertainty of the switching threshold is from 43 to 90 Vac;
• the voltage must be 230 Vac (+10/-15%), 50/60 Hz.
Example 1: connection diagram with 230 Vac inputs.
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7
J8
J20
J6
J19
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
230 VacL
N
Fig. 5.r
Example 2: connection diagram with digital inputs at diff erent voltages.
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7
J8
J20
J6
J19
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
230 VacL
N
-
+24 Vdc
Fig. 5.s
5.4 Analogue outputs
c.pCOmini: analogue outputs without optical isolation
The controller features 0 to 10 Vdc and PWM analogue outputs without
optical isolation, powered directly by the controller. See the table of the
technical specifi cations (output current, output impedance, etc., Chap. 12).
Example connection diagram (c.pCOmini model):
U1 U2 U3 GND
U4 U5 U6 GND
U7 U8 U9 U10
GNDJ1 J2
G G0 Vbat
+5VR
EFGN
D+V
DCJ9
Y1GND
ID2
ID1
Y2 GNDJ8J7
24 Vac / 28...36 Vdc
0 V
Vout
Vout
Fig. 5.t
34
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
c.pCO Small...Extralarge: 0 to 10 V analogue outputs
On terminals VG and VG0 the controller provides optically-isolated 0 to 10
V analogue outputs, to be powered externally at the same voltage as the
controller, i.e. 24 Vac or 28 to 36 Vdc. The connection diagram is shown
in the fi gure below. The 0 V supply voltage is also the voltage reference
of the outputs. See the Technical Specifi cations table for details on the
output current, output impedance, etc. (see chap. 12).
Note: • the analogue output can be connected to the CONVONOFF0 module
to convert the 0 to 10 V output into an ON/OFF relay output;
• a 0 to 10 Vdc analogue output can be connected in parallel to other
outputs of the same type, or alternatively to an external voltage
source. The higher voltage will be considered. Correct operation is not
guaranteed if actuators with voltage inputs are connected;
• if optical isolation is not required, the VG-VG0 analogue outputs can be
powered at the same voltage on G-G0: connect G0 to VG0 and G to VG.
Example connection diagram (LARGE model):
U1 U2 U3 GN
D
+VDC
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J2 J3 J4 J5 J7 J8
J20
J6
J19
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
24 Vac / 28...36 Vdc
0 V
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC13
ID14
ID14
H
Vout
Vout
Vout
Vout
Vout
Vout
Fig. 5.u
Maximum number of optically-isolated analogue outputs (ref. VG0)c.pCO model Small/Medium/Extralarge LargeOutputs Y1, Y2, Y3, Y4 Y1, Y2, Y3, Y4, Y5, Y6
5.5 Connecting the Ultracap moduleThe Ultracap module can be connected to power the controllers in the event
of blackouts:
1. c.pCOmini controller: the module guarantees temporary power to
the controller and driver for enough time to close the electronic
valve (40s with forced closing of the valve, 60s without forced closing
of the valve). NB: with Vdc power supply, forced closing of the
electronic expansion valve is not managed in the event of blackouts.
2,5 AT
24 Vac 230 Vac
40 VA
U1 U2 U3 GND
U4 U5 U6 GND
U7 U8 U9 U10
GNDJ1 J2
G G0 Vbat
G/G0: 24 V~ 50...60 Hz / 28...36 V 30 VA/12W
J3 Disp.
+Vterm
J4 FBus J5 CAN
L H
Ultracap Technology
G G0 Vbat
Fig. 5.v
35
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
2. c.pCO controller with built-in driver: the module guarantees
temporary power to the driver for enough time to close the
electronic valves.
80 VA
2.5 AT
C7
NO
7 C7
NO
8 C8
NC8
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
B6 B7 B8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J7 J8
J29
J14
J28
J17 J18J15
J6
J30
J27
VBAT
G0 G GN
D
VREF
S1 S2 S3 S4 DI1
DI2
G G0
driver
G G0
VBAT
Ultracap Technology
CAREL EXVvalve A
1 3 2 4 1 3 2 4
CAREL EXV valve B
G G0
NO
12 C12
NC1
2
J16
Fig. 5.w
5.6 Connecting the electronic valve
c.pCOmini: unipolar electronic valve
The controller incorporates the driver for connection of an unipolar
electronic expansion valve.
Note: to manage the valve, the control algorithm requires 2
probes (1 pressure probe and 1 temperature probe);
Connection example using ratiometric probes (pressure) and NTC probes (temperature).
U1 U2 U3 GND
U4 U5 U6 GND
U7 U8 U9 U10
GNDJ1 J2
G G0 Vbat
+5VR
EFGN
D+V
dc
J9
G/G0: 24 V~ 50...60 Hz / 28...36 V 30 VA/12W
Y1GND
ID2
ID1
Y2 GNDJ8
J7
CAREL E2V*, E3V* Unipolar valve
NTC
Ratiometric pressuretransducer
Fig. 5.x
c.pCO (Medium with built-in driver): bipolar electronic valve
The controller with a built-in driver can be used to control one or two
electronic expansion valves with two-pole motor.
Example connection diagram (the colour of the wires refers to the standard Carel valve cable P/N E2VCABS*00):
A B C D
C7
NO
8 C8
NC8
NO
10
J15
J27
1 3 2 4
J28
1 3 2 4
driver
VBAT
G0
G
J30
GN
D
VREF
S1 S2 S3 S4 DI1
DI2
J29
shield shield
giallo/yellow
bianco/white
verde/green
marrone/brown
NTC
driv
er A
ratio
met
ric p
ress
ure
trans
duce
r driv
er A
NTC
driv
er B
ratio
met
ric p
ress
ure
trans
duce
r driv
er B
digi
tal i
nput
to st
art t
he
regu
latio
n of
driv
er A
digi
tal i
nput
to st
art t
here
gula
tion
of d
river
B
CAREL ExV valve A CAREL ExV valve B
Fig. 5.y
Note: • connect the valve cable shield to the spade connector and then to the
earth;
• for information on the compatibility of valves and refrigerants, see the
Technical Specifi cations table (see chap. 12) and the EVD Evolution driver
manual.
On the controller with built-in valve driver it is possible to apply the
Ultracap module (accessory P/N PCOS00UC20) . The module is made
with special capacitors called ultracapacitors that close the electronic
valve in case of power failures. The module only powers the driver and
not the controller.
Important: the c.pCO with built-in driver and PCOS00UC20 module
(or EVD0000UC0 external Ultracap module, or EVBAT00400 battery) must
be powered at 24 Vac so that emergency valve closing is ensured in case
of power failures. If the controller is powered with DC voltage it will not
close the valve in case of power failures.
Note: • the built-in driver replicates all the hardware and logic functions of
the “EVD Evolution” stand-alone driver in case of 1 valve and of the
“EVD Evolution TWIN” driver in case of 2 valves. In other words, it
independently controls one or two electronic expansion valves with
two-pole stepper motors. The only diff erence with EVD Evolution is
that there are no output relays. For details on the valve control logic,
set-up and installation, see the EVD Evolution manual (+0300005EN for
single driver, +0300006EN for double driver);
• as with EVD Evolution, the built-in driver on the c.pCO controller
is available in the CAREL and the “Universal” versions. “Universal”
models are used to control both CAREL electronic expansion valves,
as well as valves produced by other manufacturers (see the Technical
Specifi cations table, chap. 12), while CAREL models only control CAREL
valves.
36
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Serial communication and programming
Communication between the c.pCO Medium and its built-in driver
is managed internally through the FBus2 serial port. The FBus2 serial
port (J26) is however electrically isolated from the driver serial line; this
ensures that in case of external faults on the line connected to FBus2,
the internal driver can keep on working independently. The driver can
only be confi gured using the c.pCO application developed with c.suite;
no external display is available for the driver.
The c.suite development environment features a module for managing
the EVD Evolution driver. When managing the built-in driver, use the
module as if managing an external driver connected to the FBus2 port.
At a c.suite application software level, the valve driver must be connected
to the FBus2 port. Consequently, any other devices physically connected
to the Fbus2 port (J26) must have the same communication protocol
(CAREL Standard Master or Modbus® Master), the same baud rate, stop
bits and parity. The built-in driver address is 198 (EVD Evolution default
address), so any other devices connected to J26 must have an address
other than 198. Communication frame confi guration is performed
by using c.suite environment. External EVD Evolution drivers can be
connected to the Fieldbus1 serial port (optional card) with no address
restrictions.
C1
NO
1
NO
2
A B C D
C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
Fie ldBus card BMS card
CAN
L
CAN
H
GND
J26 FBus2
OFF
4 3 2 1ON 1 3 2 4 1 3 2 4
driver
VBAT
G0
G GN
D
VREF
S1 S2 S3 S4 DI1
DI2
VBATG
0G
EXV connectionPower Supply Relay
NO
1
COM
14231
GN
D
V RE
F
S1 S2 S3 S4 DI1
DI2
Anal og – Digital Input Network
GND Tx/Rx
VBATG
0G
EXV connectionPower Supply Relay
NO
1
COM
14231
GN
D
V RE
F
S1 S2 S3 S4 DI1
DI2
Anal og – Digital Input Network
GND Tx/Rx
VBATG
0G
EXV connectionPower Supply Relay
NO
1
COM
14231
GN
D
V RE
F
S1 S2 S3 S4 DI1
DI2
Anal og – Digital Input Network
GND Tx/Rx
VBATG
0G
EXV connectionPower Supply Relay
NO
1
COM
14231
GN
D
V RE
F
S1 S2 S3 S4 DI1
DI2
Anal og – Digital Input Network
GND Tx/Rx
VBATG
0G
EXV connectionPower Supply Relay
NO
1
COM
14231
GN
D
V RE
F
S1 S2 S3 S4 DI1
DI2
Anal og – Digital Input Network
GND Tx/Rx
VBATG
0G
EXV connectionPower Supply Relay
NO
1
COM
14231
GN
D
V RE
F
S1 S2 S3 S4 DI1
DI2
Anal og – Digital Input Network
GND Tx/Rx
ADDR≠198 ADDR≠198 ADDR≠198
ADDR =198
ADDR =198
Fig. 5.z
Important: to ensure effi cient data exchange between the driver
and the controller, when developing the c.suite application, if there are
devices connected to the FBus2 port (terminal J26) using the Modbus®
protocol, developers should take into account the number of variables
exchanged over the entire serial line.
5.7 Digital outputs
Electromechanical relay digital outputs
The controller features digital outputs with electromechanical relays. For
ease of installation, the common terminals of some of the relays have
been grouped together. Some relays feature changeover contacts.
Relays with changeover contactsc.pCO model
mini - c.pCOe Small Medium / Extralarge LargeOutput no. 6 8 8, 12, 13 8, 12, 13
The type of insulation is described in the table below. See also the
Technical Specifi cations table in chap. 12.
c.pCOmini - c.pCOeType of insulation
Between relays in group 1 & 2 basic insulationBetween relays in group 3 and in group 1 & 2 reinforced insulation
Note:• between groups 1 and 2 there is basic insulation, and these must
therefore have the same voltage (generally 24 Vac or 110/230 Vac);
• between the relay groups 1 and 2 and group 3 there is reinforced
insulation, and so group 3 can have a diff erent voltage.
c.pCO Small...ExtralargeType of insulation
Between relays in same group functional insulation Between groups of relays reinforced insulationBetw. relays and rest of controller reinforced insulation
Note:• inside each group, the relays have just functional insulation and must
therefore have the same voltage (generally 24 Vac or 110/230 Vac);
• between groups there is reinforced insulation, so diff erent groups can
have diff erent voltages.
Example connection diagram (LARGE model):
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
J21
J14J13J12
J22
J16 J17 J18J15
NO
14 C14
NC1
4
NO
15 C15
NC1
5
C16
NO
16
NO
17
NO
18 C16
J23 FBus2J25 BMS2 J26 FBus2
4 3 2 1
N
L
110/230-24Vac
Fig. 5.aa
C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
J21
J14J13
J22
J16 J17 J18J15
NO
14 C14
NC1
4
NO
15 C15
NC1
5
C16
NO
16
NO
17
NO
18 C16
J23 FBus2S2 J26 FBus2
4 3 2 1
N
L
110/230-24Vac
Fig. 5.ab
Important: the current on the common terminals must not exceed
the capacity (rated current) of each single terminal (8 A).
37
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Remote connection of digital outputs
The table below shows the cable sizes required according to the current.
Cross-section (mm2)/AWG Current (A)0,5/20 21,5/15 62,5/14 8
Note: when diff erent relay outputs must be operated consecutively
at very close intervals (e.g. star-delta motor starter) in the order of
hundreds of ms, use relays belonging to the same group, according to
the following table.
c.pCOmini - c.pCOerelay groups for consecutive commands (~ 100 ms)
1 2 3
Relay 1, 2 3,4,5 6
c.pCO Small...Extralargerelay groups for consecutive commands (~ 100 ms)
1 2 3 4 - c.pCO Large
4 - c.pCO ExtraLarge 5
Relay 1, 2, 3, 45, 6,
7, 8
9, 10, 11,
12, 13
14, 15, 16,
17, 18
14, 15, 16, 17, 18,
19, 20, 21
22, 23, 24, 25,
26, 27, 28, 29
Important: using relays that belong to diff erent groups can cause
delays in switching.
5.8 Solid state relay (SSR) digital outputs c.pCO controllers are also available in versions with solid-state relays (SSR)
for controlling devices that require an high number of switching cycles that
would not be supported by electromechanical relays. These outputs are
dedicated to resistive loads powered at 224 Vac SELV or 28 to 36 Vdc SELV
with max. load current up to 1 A or 230 Vac with max. load current up to
70 mA.
Example 1: connection diagram for resistive load.
NO
1
NO2
NO3
C1
C4
NO
4
NO5
NO
6
C4
C7
NO7
C7
NO8
C8
NC8
24 Vac/Vdc
Fig. 5.ac
Example 2: connection diagram for inductive or resistive loads, with max. load current < 1 A.
NO5
NO
6
C4
C7
NO7
C7
NO8
C8
NC8
24 Vac/Vdc
(*)
SSR ESTERNO/EXTERNAL SSR
carico/load
inp
ut
Fig. 5.ad
(*) dedicated power supply or same power supply as controller: not in
common with the power supply for other external loads (e.g. contactors,
coils).
Important: in applications with SSR outputs:
• the controller should only power resistive loads with load current less
than maximum declared;
• use an additional external SSR to power inductive loads;
• for AC power supply to resistive loads or external SSRs, use the same
power supply as the controller (connected to terminals G/G0), which
must be dedicated and not in common with the power supply to other
devices in the electrical panel (contactors, coils, etc.)
Note: the SSR load is powered at 24 Vac SELV, 28 to 36 Vdc SELV or
230 Vac; consequently all the other terminals in the group must be
powered at the same voltage due to the absence of reinforced insulation
within the group.
38
MINI
digital input 1
digital input 2
out H
M
NTC
NTC
+ (G)
probe 7-8
probe 4 Carel NTCprobe 5 Carel NTCprobe 6 voltage-free/digital input
probe 9 voltage-free/digital inputprobe 10 voltage-free/digital input
probe 1 (0/5V)
230/24 Vac
LN
2,5 A T
analog output 1 (0...10 Vdc)
analog output 2 (0...10 Vdc)
M
OUT
+V
probe 2 (4/20 mA)
probe 3 (0/1 Vdc or 4/20 mA))
digital output 1digital output 2digital output 3
digital output 4
digital output 5digital output 6
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
5.9 General connection diagram c.pCOmini
Fig. 5.ae
39
SMA
LLM
EDIU
MLA
RGE
230/24 Vac
M
OUT
+V
analog output 1 (0...10 Vdc)
analog output 2 (0...10 Vdc)
analog output 3 (0...10 Vdc)
analog output 4 (0...10 Vdc)
analog output 5 (0...10 Vdc)
digital output 1digital output 2digital output 3
digital output 4
digital input 1digital input 2digital input 3digital input 4digital input 5digital input 6digital input 7digital input 8
digital input 15
digital input 16
digital input 17digital input 18
digital output 5digital output 6
digital output 7
digital output 8
digital output 14
digital output 15
digital output 16digital output 17digital output 18
probe 9 CAREL NTC
probe 10voltage-freedigital input
analog output 6 (0...10 Vdc)
G
G0
B1
B2
B3
GND
GND
B4
BC4
B5
BC5
VG0
Y1
Y2
Y3
Y4
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
out H
M
NTC
NTC
+ (G)
digital input 9
CP
digital input 10digital input 11digital input 12
digital input 13
digital input 14
digital output 9digital output 10digital output 11
digital output 12
digital output 13
probe 8 CAREL NTC
probe 6 - 7
50VA
2.5 AT
C1
NO1
NO2
NO3
C1
C4
NO4
NO5
NO6
C4
C7
NO7
C7
NO8
C8
NC8
G
G0
U1
U2
U3
GND
+VDC
+Vterm
GND
+5 VREF
U4
GND
U5
GND
VG
VG0
Y1
Y2
Y3
Y4
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
J1J24
J2J3
J4J5
J14
J10
J13J12
J15
Field
Bu
s cardB
MS
card
J11 pLAN
J25 BMS2
J26 FBus2
43
21
NO12
C12
NC12
NO13
C13
NC13
C9
NO9
NO10
NO11
C9
IDC1
U6
U7
U8
GND
ID9
ID10
ID11
ID12
IDC9
ID13H
ID13
IDC13
ID14
ID14H
J7J8
J16J17
J18
J6
J20
J21J22
J19
NO14
C14
NC14
NO15
C15
NC15
C16
NO16
NO17
NO18
C16
ID15H
ID15
IDC15
ID16
ID16H
Y5
Y6
ID17
ID18
IDC17
U9
GND
U10
GND
J23 FBus2
probe 1 (0/5 V)
probe 2 (4/20 mA)
probe 3 (0/1 Vdc or 4/20 mA)
probe 4 Carel NTC
probe 5 PT1000
XXXXXXXXXXXX
N
L
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
5.10 General connection diagram c.pCO
Fig. 5.af
40
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
6. START-UP
6.1 Switching onWhen the controller is switched on, it runs a test on the secondary display,
lighting up the segments one by one.
6.2 Private and shared terminalAll c.pCO controllers can be connected to each other in a local area
network (pLAN, see Figure 6.a) in order to share one or more terminals.
Shared terminals can show the variables (temperature, humidity, pressure,
I/O, alarms) from just one controller at a time. The terminal does not need
to be connected to the controller during normal operation, but can be
used just for the initial programming of the main parameters. If one or
more terminals are disconnected or malfunctioning, the application
program continues to work correctly on each controller. Generally, the
application program can monitor the status of the network and intervene
as necessary to ensure continuity of the control functions. The fi gure
below shows a possible pLAN network connection diagram.
pGDE/pGD1
pLAN (RS485)
c.pCO: ADDR=1
C1
NO1
NO2
NO3
C1
C4
NO4
NO5
NO6
C4
C7
NO7
C7
NO8
C8
NC8
NO12
C12
NC12
NO13
C13
NC13
C9
NO9
NO10
NO11
C9
G
G0
U1
U2
U3
GND
+VDC
+Vterm
GND
+5 VREF
U4
GND
U5
GND
VG
VG0
Y1
Y2
Y3
Y4
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6
U7
U8
GND
ID9
ID10
ID11
ID12
IDC9
ID13H
ID13
IDC13
ID14
ID14H
J1J24
J2J3
J4J5
J7
J8
J20
J21
J14
J10
J13J12
J22
J16J17
J18J15
J6
J19
NO14
C14
NC14
NO15
C15
NC15
C16
NO16
NO17
NO18
C16
ID15H
ID15
IDC15
ID16
ID16H
Y5
Y6
ID17
ID18
IDC17
U9
GND
U10
GND
Field
Bu
s cardB
MS
card
J23 FBus2
input: 24 V 50...60 Hz / 28...36 V
max. pow
er: 45 VA/20 W J11 pLAN
J31
CANL
CANH
GND
J25 BMS2
J26 FBus2
OFF
43
21
ON
c.pCO: ADDR=2
C1
NO1
NO2
NO3
C1
C4
NO4
NO5
NO6
C4
C7
NO7
C7
NO8
C8
NC8
NO12
C12
NC12
NO13
C13
NC13
C9
NO9
NO10
NO11
C9
G
G0
U1
U2
U3
GND
+VDC
+Vterm
GND
+5 VREF
U4
GND
U5
GND
VG
VG0
Y1
Y2
Y3
Y4
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6
U7
U8
GND
ID9
ID10
ID11
ID12
IDC9
ID13H
ID13
IDC13
ID14
ID14H
J1J24
J2J3
J4J5
J7
J8
J20
J21
J14
J10
J13J12
J22
J16J17
J18J15
J6
J19
NO14
C14
NC14
NO15
C15
NC15
C16
NO16
NO17
NO18
C16
ID15H
ID15
IDC15
ID16
ID16H
Y5
Y6
ID17
ID18
IDC17
U9
GND
U10
GND
Field
Bu
s cardB
MS
card
J23 FBus2
input: 24 V 50...60 Hz / 28...36 V
max. pow
er: 45 VA/20 W J11 pLAN
J31
CANL
CANH
GND
J25 BMS2
J26 FBus2
OFF
43
21
ON
Fig. 6.a
All the terminals and controllers in the network must communicate at the
same speed. The speed is adapted automatically.
A maximum of 32 units can be connected, including:
• c.pCO controllers, which run the control program;
• terminals.
Every device belonging to a pLAN network is identifi ed by a unique
address, i.e. a number from 1 to 32. The number 32 can be assigned only to
a terminal. Programs for diff erent applications (e.g. chillers, air-conditioners,
compressor racks, etc.) cannot be automatically integrated into a local
network – they must be confi gured according to the system architecture
using the CAREL development tool.
Each controller connected to the network can simultaneously manage
up to 3 terminals in the pLAN network. The values are displayed on the
terminals at the same time and not independently, as if the keypads and
the displays were connected in parallel. Because of that, the controller
cannot manage diff erent kinds of terminals at the same time.
Each terminal associated with a certain controller is defi ned as:
- private (“Pr”) if it displays only the output of that controller;
- shared (“Sh”) if either automatically or from the keypad it can be switched
between various controllers.
Each c.pCO constantly updates the displays on the private terminals, while
the shared terminals (if present) are updated only by the c.pCO that is
controlling the terminal at that time.
The fi gure below illustrates the logic of the relationships:
C1
NO1
NO2
NO3
C1
C4
NO4
NO5
NO6
C4
C7
NO7
C7
NO8
C8
NC8
NO12
C12
NC12
NO13
C13
NC13
C9
NO9
NO10
NO11
C9
G
G0
U1
U2
U3
GND
+VDC
+Vterm
GND
+5 VREF
U4
GND
U5
GND
VG
VG0
Y1
Y2
Y3
Y4
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6
U7
U8
GND
ID9
ID10
ID11
ID12
IDC9
ID13H
ID13
IDC13
ID14
ID14H
J1J24
J2J3
J4J5
J7
J8
J20
J2 1
J14
J10
J13J12
J22
J16J17
J18J15
J6
J19
NO14
C14
NC14
NO15
C15
NC15
C16
NO16
NO17
NO18
C16
ID15H
ID15
IDC15
ID16
ID16H
Y5
Y6
ID17
ID18
IDC17
U9
GND
U10
GND
Fie
ldBus ca
rdBMS
card
J23 FBus2
input: 24 V 50...60 H
z / 28...36 Vmax. p
ower: 45 VA
/20 W J11 pLAN
J25 BMS2
J26 FBus2
43
21
C1
NO1
NO2
NO3
C1
C4
NO4
NO5
NO6
C4
C7
NO7
C7
NO8
C8
NC8
NO12
C12
NC12
NO13
C13
NC13
C9
NO9
NO10
NO11
C9
G
G0
U1
U2
U3
GND
+VDC
+Vterm
GND
+5 VREF
U4
GND
U5
GND
VG
VG0
Y1
Y2
Y3
Y4
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6
U7
U8
GND
ID9
ID10
ID11
ID12
IDC9
ID13H
ID13
IDC13
ID14
ID14H
J1J24
J2J3
J4J5
J7
J8
J20
J2 1
J14
J10
J13J12
J22
J16J17
J18J15
J6
J19
NO14
C14
NC14
NO15
C15
NC15
C16
NO16
NO17
NO18
C16
ID15H
ID15
IDC15
ID16
ID16H
Y5
Y6
ID17
ID18
IDC17
U9
GND
U10
GND
Fie
ldBus ca
rdBMS
card
J23 FBus2
input: 24 V 50...60 H
z / 28...36 Vmax. p
ower: 45 VA
/20 W J11 pLAN
J25 BMS2
J26 FBus2
43
21
C1
NO1
NO2
NO3
C1
C4
NO4
NO5
NO6
C4
C7
NO7
C7
NO8
C8
NC8
NO12
C12
NC12
NO13
C13
NC13
C9
NO9
NO10
NO11
C9
G
G0
U1
U2
U3
GND
+VDC
+Vterm
GND
+5 VREF
U4
GND
U5
GND
VG
VG0
Y1
Y2
Y3
Y4
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6
U7
U8
GND
ID9
ID10
ID11
ID12
IDC9
ID13H
ID13
IDC13
ID14
ID14H
J1J24
J2J3
J4J5
J7
J8
J20
J2 1
J14
J10
J13J12
J22
J16J17
J18J15
J6
J19
NO14
C14
NC14
NO15
C15
NC15
C16
NO16
NO17
NO18
C16
ID15H
ID15
IDC15
ID16
ID16H
Y5
Y6
ID17
ID18
IDC17
U9
GND
U10
GND
Fie
ldBus ca
rdBMS
card
J23 FBus2
input: 24 V 50...60 H
z / 28...36 Vmax. p
ower: 45 VA
/20 W J11 pLAN
J25 BMS2
J26 FBus2
43
21
c.pCO: 4
c.pCO: 1 pGDE Private
pGDE Private pGDE Private
pGDE Private
pGDE/pGD1 Shared
1
34
2
c.pCO: 2
C1
NO1
NO2
NO3
C1
C4
NO4
NO5
NO6
C4
C7
NO7
C7
NO8
C8
NC8
NO12
C12
NC12
NO13
C13
NC13
C9
NO9
NO10
NO11
C9
G
G0
U1
U2
U3
GND
+VDC
+Vterm
GND
+5 VREF
U4
GND
U5
GND
VG
VG0
Y1
Y2
Y3
Y4
ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6
U7
U8
GND
ID9
ID10
ID11
ID12
IDC9
ID13H
ID13
IDC13
ID14
ID14H
J1J24
J2J3
J4J5
J7
J8
J20
J2 1
J14
J10
J13J12
J22
J16J17
J18J15
J6
J19
NO14
C14
NC14
NO15
C15
NC15
C16
NO16
NO17
NO18
C16
ID15H
ID15
IDC15
ID16
ID16H
Y5
Y6
ID17
ID18
IDC17
U9
GND
U10
GND
Fie
ldBus ca
rdBMS
card
J23 FBus2
input: 24 V 50...60 H
z / 28...36 Vmax. p
ower: 45 VA
/20 W J11 pLAN
J25 BMS2
J26 FBus2
43
21
c.pCO: 5
Fig. 6.b
In this example, the shared terminal is associated with 4 controllers, but
at this instant only controller 1 can display data and receive commands
from the keypad. Switching between controllers occurs:
1. using a command in the system menu;
2. in sequence (1->2->3->4->1...) by pressing a button defi ned by the
application program; however it can also be done automatically
when requested by the program. For example, a c.pCO may request
control of the shared terminal to display alarms or, vice-versa,
relinquish control to the next c.pCO after a set time (cyclical rotation).
Data on the number and type of terminals is determined during initial
network confi guration and saved in the permanent memory of each
c.pCO controller. Details of the confi guration procedure are described
below. See the “Installation” chapter for information on the cables to use
for the electrical connections.
6.3 Setting the controller pLAN addressThe controller pLAN address is factory-set as 1.
There are two ways to set a controller address:
1. using button A (see the fi gure below) located next to the 7-segment
display. This can be accessed using the tip of a screwdriver (ø<3 mm);
2. from the system menu (see Chapter 7).
Displaying the pLAN address
The pLAN address is displayed permanently on the pLAN address display.
NO1
C1/2
NO2
NO3
C3/4
/5
NO4
J10 J11
ID1J7
GND
U5 GND
VG VG0
Y1
J3 J4
card
Fig. 6.c
41
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Setting the pLAN address
Procedure 1 - by button
• press button A for 5 seconds: the pLAN address is displayed brighter;
• press repeatedly: the address is incremented
• release the button: after a few seconds, brightness is decreased and
the pLAN address is saved in the memory
A
A
G G0 U1 u2 U3 GND
+VDC
+Vte
rm
GND
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID
J1 J24 J2 J3 J4 J5
Fie ldBus card BMS card
Fig. 6.d
Procedure 2 - system menu
1. press Alarm and Enter together for 3 s and enter the system menu.
Select settings;
INFORMATIONSETTINGSAPPLICATIONUPGRADELOGGERDIAGNOSTICS
2. select pLAN settings;
PASSWORDUSB SETTINGSPLAN SETTINGSCLOCK SETTINGSTCP/IP SETTINGS
3. modify the controller pLAN address and confi rm by selecting
"Update confi guration".
pLAN pCO Addr:7
Release Term:NoAcquire Term:No
Update config:yes
6.4 Setting the terminal address and
connecting the controller to the terminalAfter setting the controller network address (see previous paragraph),
to establish connections between the controller and the terminal, the
terminal address needs to be set. If the controller is connected to an
external terminal with address 32 (default setting), communication
is established (if the built-in terminal is present, the external terminal
replicates the same visualization). To confi gure multiple terminals, private
and/or shared, diff erent addresses need to be assigned to the terminals,
and the controller must be properly confi gured:
1. To confi gure the address of the terminal, press the UP, DOWN and
Enter buttons together for 3 seconds. The screen is displayed in Fig 6.e.
Modify the address of the terminal (in the range 1 to 32) and confi rm
by pressing Enter.
Display addresssetting........... 32
I/O Board Address: 01
2. A screen is displayed showing the list of the terminals confi gured.
Set the terminals as private (Priv) or shared (Shared) according to the
application, and confi rm to exit. After a few seconds, the connection
will be established.
P:01 Adr Priv/SharedTrm1 21 ShTrm2 22 ShTrm3 23 Sh OK?Yes
3. To add a second terminal, repeat the previous steps.
6.5 Sharing terminals in a pLAN networkOnce connected in a network (pLAN), the c.pCO controllers can share
the same pGD terminal. A shared terminal may be needed, for example,
to install an update to the operating system and/or application program.
Connect the controllers and terminals to the network (Figure 6.g). Set
the pLAN address for each controller using the dedicated button (see
paragraph 6.3), and for each terminal using the corresponding procedure).
The fi gure below represents three c.pCO controllers in a pLAN network
with three pGD displays, each with their own address.
Term 1Addr: 21
Term 2Addr: 22
Term 3Addr: 23
c.pCOAddr:1
c.pCOAddr: 3
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
J1 J24 J2 J3
J10
Fie ldBus card
J11 pLAN
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
J1 J24 J2 J3
J10
Fie ldBus card
J11 pLAN
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
J1 J24 J2 J3
J10
Fie ldBus card
J11 pLAN
c.pCOAddr: 2
A B
Fig. 6.e
1. To set the address on each terminal (Term1, Term2, Term3), see par. 6.4.
2. Enter the address of the three terminals and set them as “shared”. This
operation should be repeated for each of the three terminals (see
paragraph 6.4).
P:01 Adr Priv/SharedTrm1 21 ShTrm2 22 ShTrm3 23 Sh OK?Yes
42
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Acquire/ release commands
These commands are used by a controller to acquire / release a terminal.
Procedure:
1. Press Alarm and ENTER together to enter the system menu. Select
“Settings”
INFORMATIONSETTINGSAPPLICATIONUPGRADELOGGERDIAGNOSTICS
2. Select pLAN Settings
PASSWORD USB SETTINGS PLAN SETTINGS CLOCK SETTINGS TCP/IP SETTINGS
3. The following screen is shown, where the acquire/release
commands can be activated.
pLan pCO Addr: 1
Release Term: NoAcquire Term: No
Update config: No/Yes
KeypLan pCO addr. Address of c.pCO controller currently connected to the
terminalRelease terminal Release commandAcquire terminal Acquire commandUpdate confi gu-
ration
Confi rm update
Command virtualisation
Whenever a pGD terminal is connected to a c.pCO, the pGD terminal
displays the corresponding user interface. The command is sent from
the terminal, however it is the controller that executes the operation to
release or acquire the terminal.
Example 1
A: the release command on terminal 21 releases c.pCO 3 from terminal
21, and this is then assigned to c.pCO 1;
B: the release command on terminal 21 releases c.pCO 1 from terminal 21,
and this is then assigned to c.pCO 2.
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
Term 21:Release term
A B
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
Term 21:Release term
Example 2
A: the release command on terminal 22 releases c.pCO 3 from terminal
21, and this is then assigned to c.pCO 1;
B: the release command on terminal 22 releases c.pCO 3 from terminal 22,
and this is then assigned to c.pCO 1.
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
Term 22:Release term
A B
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
Term 22:Release term
Example 3
A: the acquire command on terminal 22 acquires c.pCO 1 on terminal 21,
and this is thus assigned to c.pCO 1;
B: the acquire command on terminal 22 has no eff ect, as c.pCO 1 has
already acquired all the terminals
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
Term 22:Release term
A B
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
drac SMBdrac suBdleiF
XXXXXXXXXXXX
c.pCO
c.pCO
c.pCO
pGD
pGD
pGD
1
2
3
21
22
23
Term 22:Release term
6.6 Uploading/updating the softwareIt is possible to load/update the application software of the c.pCO
controllers family with the following methods:
• Update from computer by using c.factory (via USB or Ethernet
connection
• Update via USB fl ash drive
• Update with fi le transfer via FTP
• Update via tERA cloud service
The c.factory software is part of the “c.suite”, but it can be also installed
individually, downloading it from http://ksa.carel.com under “Software &
Support”->“c.suite”.
Update from computer using c.factory
On all c.pCO family controllers, the application program can be uploaded
by using the c.factory software, with direct connection to the controller
via USB cable or Ethernet network. To upload the application program,
proceed as follows:
a) Update from computer using c.factory via Ethernet connection:
Confi gure the computer and the c.pCO controller so that they belong to
the same LAN (see paragraph 9.2).
1. Open c.factory and select the application program fi le compiled in
c.strategy tool (“.otr” fi le extension). The tool will list the confi gurations
defi ned in c.design. Select the confi guration to be loaded on the
controller and click “next”.
Fig. 6.f
43
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
2. Select the fi les to be loaded on the controller and “Ethernet
Connection” type. By pressing "Discover" it is possible to list the c.pCO
controllers available in the LAN. Select the MAC address of the c.pCO
controller to be updated, and click “upload”:
Fig. 6.g
Note: if the c.pCO controller contains an application program that
is protected by a diff erent password or digital signature than the new
application program, a dialogue box will be shown prompting for the
password. If the password entered is correct, the new application
program can be uploaded.
3. At the end of the update procedure, the c.pCO controller
restarts automatically with the new application program (or new
confi guration).
b) Update via USB connection:
Connect the computer to the c.pCO controller via USB cable using the
device USB port.
USB connectorfrom computer
BMS card
Fig. 6.h
1. Open c.factory and select the application program fi le compiled
in c.suite (“.otr” fi le extension). The tool will list the confi gurations
defi ned in c.design. Select the confi guration to be loaded on the
controller and click “next”.
Fig. 6.i
2. Select the fi les to be loaded on the controller and “USB Connection”
type. Select the serial port that the c.pCO controller is connected to
via USB cable and click “upload”:
Fig. 6.j
Note: if the c.pCO controller contains an application program that
is protected by a diff erent password or digital signature than the new
application program, a dialogue box will be shown prompting for the
previous password. If the password entered is correct, the new application
program can be uploaded.
3. At the end of the update procedure, the c.pCO controller
restarts automatically with the new application program (or new
confi guration).
Important: before updating the c.pCO controller via USB
connection, check in the system menu that the Device USB port is
enabled (Settings --> USB Settings --> PC connection, see Chapter 7).
Update via USB fl ash drive
All models in the c.pCO family come with a host USB port that can be
connected to a USB mass storage device (typically a USB fl ash drive or
portable hard drive), from which an application program can be loaded
onto the c.pCO programmable controller.
To update the controller, the application fi le with extension .ap1 needs to
be created in c.factory and loaded onto the USB fl ash drive:
1. Open c.factory and select the application program fi le compiled
in c.suite (“.otr” fi le extension). The tool will list the confi gurations
defi ned in c.design. Select the confi guration to be loaded on the
controller and click "next”.
Fig. 6.k
44
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
2. Select the fi les to be loaded onto the controller and click ”Export
Ap1”. In the application package it is possible to include also:
• the Operating System, selecting the specifi c path;
• the web pages for the c.pCO web server functionality (see Chapter 10).
Fig. 6.l
3. Click “Export” and save the fi le to a fl ash drive, under a directory called
“UPGRADE”.
4. Plug the fl ash drive into the Host USB port and enter the system
menu (see Chapter 7). On the screen, select UPGRADE and then the
application program to be loaded and confi rm by pressing enter.
USB keyA
Fig. 6.m
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
Important: • Before updating the c.pCO controller via USB connection, check in
the system menu that the Host USB port is enabled (Settings --> USB
Settings --> Pen drive, see Chapter 7).
• Only use fl ash drives with FAT fi le system.
• Do not use both USB ports on the controller at the same time.
• Do not use mass storage peripherals that have a current draw more
than 500 mA.
Update with fi le transfer via FTP
The c.pCO family controllers fi tted with Ethernet port include an FTP
server that provides access to the public partition of the fi le system.
Files and directories in this partition can be read, modifi ed, created and
deleted. FTP can also be used to transfer an .ap1 fi le, for example to
update the image of the operating system or the application program.
This is done using an FTP client, for example “FileZilla”.
To protect the contents of the public fi le system against unauthorised
access, diff erent users can be created, assigning each a diff erent access
profi le, dedicated to each service and adapted to the individual directory
(see Chapter 9). To update via FTP:
1. Open an FTP client (e.g. FileZilla). Enter the IP address of the c.pCO
controller and the access credentials (default user “anonymous”, no
password).
2. Drag & drop the software update fi le from the directory on the
computer to the “UPGRADE” directory on the c.pCO controller.
Fig. 6.n
Nota: Please use following settings in Filezilla:
• Edit->Settings->Connection-> set timeout in seconds = 0
• Edit -> Settings -> Transfers -> set maximous simultaneous transfers to 1
3. Access the system menu on the c.pCO and select “UPGRADE” (see
Chapter 7).
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
Note: when having loaded the update fi le to the “UPGRADE”
directory via FTP, the update procedure can also be started using the
virtual terminal (see paragraph 10.3).
Update via tERA cloud service.
See paragraph 10.6.
45
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
6.7 c.pCOe expansion board: installation
and confi gurationc.pCOe is an I/O expansion module compatible with the c.pCO and pCO
sistema platforms. The module features:
• 10 universal inputs/outputs that can be confi gured in the
application program to connect active and passive probes, digital
inputs, analogue and PWM outputs.
• 6 relay digital outputs, divided into 3 groups (see paragraph 5.7)
• Power supply terminals for ratiometric probes and active probes
• Built-in BMS serial interface
• Dipswitches for confi guring the communication protocol and serial
address
12345678
9101112131415 with offset
no offset
19.2 K9.6 K38.4 K57.6 K
CARELModbus
ONOFF
Address Ext. ProtBaud
Address Ext Baud Prot
Fig. 6.o
12345678
9101112131415 with offset
no offset
19.2 K9.6 K38.4 K57.6 K
CARELModbus
ONOFF
Address Ext. ProtBaud
Fig. 6.p
Note: the green LED indicates communication status on the BMS
port. If there is communication on the BMS port (online) the green LED
fl ashes, if there is no communication (offl ine) the LED stays on steady.
Important: Power supply to the product must only be connected
between G and G0. The Vbat terminal is only used for connection to the
Ultracap module as emergency power supply in the event of a power
failure.
The dipswitches can be used to set the expansion board serial address
(from 1 to 15), protocol (Modbus or Carel) and baud rate. By serial
connection it is possible to modify the electrical confi guration of the line
and assign a serial address from 16 to 247 (207 if using the Carel protocol).
Baud rate and communication protocol settings
Board default confi guration is baud rate 19.2 Kbps and Modbus protocol.
The “Baud” and “Prot” dipswitches (see Fig. 6.u) can be used to set the baud
rate and the communication protocol used by the expansion board. The
unit must be switched off before making the settings on the dipswitches.
Important: if the baud rate and protocol settings are changed on
the dipswitches while the unit is on, this must be restarted to activate the
new settings.
Address and serial communication mode settings
To assign to the board a serial address from 1 to 15, simply set the
dipswitches as shown in Figure 6.u. The “Ext” dipswitch must be set to
“OFF” (no off set). The unit must be switched off before making the
settings on the dipswitches.
Important: if the settings are changed on the dipswitches while
the unit is on, this must be restarted to activate the new settings.
To assign to the the board a serial address from 16 to 247 and to confi gure
the serial communication settings, an off set needs to be sent to the
expansion board via serial communication, which is then added to the
“Address” dipswitch confi guration, and the variable corresponding to the
serial transmission parameters needs to be set, as follows:
Example (address setting N=87, serial communication 8, Even, 1):1. Set the dipswitches of the “Address” group and the dipswitch “Ext.”
a OFF.
2. Restart the unit. The c.pCOE will go into “Set Mode”. Warning: activating this mode resets both the address off set and the serial communication settings. In this mode, the board serial address will
be 207 and the serial confi guration will be 8 bits, no parity and 2 stop
bits (8 bits, None, 2). The yellow LED fl ashes.
3. To set the communication parameters, the “Serial Transmission
Confi guration” variable needs to be set via serial communication
(see Table 6.a and 6.b). In this example, the variable is set to 5
(confi guration 8, Even, 1).
4. To set the serial address, the “Address Extension” off set variable needs
to be set via serial communication (the off set must be greater than
14, see Table 6.a). In this example, it can be set to 86.
5. Move the “Ext” dipswitch to ON. Set the “Address” dipswitches to a
value greater than 0. In this example, the value is set to 1.
6. Restart the unit. After restarting, the expansion card will be
confi gured with the serial address calculated as the sum of the value
set for the “Address Extension” variable and the value set on the
“Address” dipswitches (in this example 86 + 1 = 87). After restarting,
the expansion card will have the serial communication confi guration
8, Even, 1.
Variable Carel Address(Integer)
Min Value Carel
Max Value Carel
Modbus Address(Holding Regi-ster)
Min Value Modbus
Max Value Modbus
Address
Extension
14 15 192 14 15 232
Serial Confi -
guration
17 0 5 17 0 5
Tab. 6.a
Important:
• If using the Carel protocol, the maximum settable off set is 192.
• The following confi gurations are not allowed:
- The “Ext” dipswitch cannot be ON with an off set equal to 0 (“Address
Extension” variable = 0). In this case, the card will signal a confi guration
error, with the yellow LED on steady. The green LED remains on,
indicating that the card is offl ine.
- The “Ext” dipswitch cannot be ON with an off set other than 0 and
the “Address” dipswitches set to 0 (all OFF). In this case, the card will
signal a confi guration error, with the yellow LED fl ashing. The green
LED remains on, indicating that the card is offl ine.
Serial Confi gurationValue Confi guration
0 8, none, 21 8, none, 12 8, odd, 23 8, odd, 14 8, even, 25 8, even, 1
Tab. 6.b
46
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
7. SYSTEM MENU
7.1 Menu treePress Alarm and Enter together for 3 seconds to enter the menu tree:
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
Fig. 7.a
INFORMATIONPCO INFORMATION
PLAN INFO
I/O INFO
FYLESYSTEM INFO
SETTINGS PASSWORD
TERMINALSETTINGS
USB SETTINGS
CLOCKSETTINGS
TCP/ IP SETTINGS
APPLICATIONSTOP APPLICATION
RESTARTAPPLICATION
STARTAPPLICATION
WIPE RETAIN
WIPE NVRAM
BUILT IN SETTINGS
UI MANAGEMENT
LOGGER EXPORT LOGS
FLUSH LOGS
RESTART LOGS
WIPE LOGS
APPLICATION INFO
BUILT IN INFO
TASK INFO
MEMORY INFO
UPGRADE DIAGNOSTICS SYSTEM LOGS
Fig. 7.b
Below is the description of the screens that will be displayed during
navigation:
INFORMATION
PCO INFORMATION:PCO INFORMATION:
Mask description DescriptionBT v.x.xxx xxxx/xx/xx Bootloader version
OS v. x.xxx xxxx/xx/xx
Operating System version
SVN REV xxxxMAC xx-xx-xx-xx-xx-xx Ethernet card MAC address, also shown
on the label above the Ethernet port
S/N xxxxxxxxxxxxxxxx Serial number, also shown on the
product label
tERA xxxxxxxx Code for activating the tERA service
I/O INFO:I/O INFO:
Mask description Description1 FW xx.xx HW xx.xx HW and SW version of the I/O chip
2 FW xx.xx HW xx.xx3 FW xx.xx HW xx.xx4 FW xx.xx HW xx.xx
MEMORY INFO:MEMORY INFO:
MEM MANAGEMENTMask description Descriptionused memory: xxxxxx byte
Free and used RAM (nominal RAM 16
Mbytes)
available memory: xxxxxxxx byte
PLAN INFO:PLAN INFO:
Mask description DescriptionpLAN Address Display pLAN address and terminals
assigned
ENTER to graph net Graphic view of the pLAN network
FYLESYSTEM INFO:FYLESYSTEM INFO:Volume 0 comprises 32 Mbytes, and cannot be accessed directly, consequently
the application program can only be copied to this location from c.suite.
Volume 1 comprises 96 Mbytes of NAND fl ash memory available to the user.
By USB device port, or FTP protocol it is possible to access this public fi le
system in order to save applications, documents, web pages, system logs.
MSD: fl ash drive recognition on host port.
volume size freenand: 0 30 xx MBnand: 1 91 xx MBmsd: 0 0 0 MB
TASK INFO: ReservedTASK INFO: Reserved
APPLICATION INFO:APPLICATION INFO:
APPLICATION STATISTICSMask description Descriptionused memory: xxx K RAM, xxx K ROMxxx K code, xx K dataxx K VM, 0 K chng (change)xxx K conf (configuration), xx K prot (protocol)
Information on the application
program, used for diagnostics
cycle time:xx ms last, xxx ms max
Application program cycle time,
depending on the complexity
BUILT -IN INFO:BUILT -IN INFO:
Mask description DescriptionBuilt - in type:xx Information on the built-in display, if
featuredFW release: x.xx
47
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
APPLICATION
Mask description DescriptionSTOP APPLICATION To stop/re-start execution of the applica-
tion programSTART APPLICATIONRESTART APPLICATION Corresponds to STOP + START
WIPE RETAIN The "Retain" variables return to the default
values
WIPE NVRAM Clear clock or RAM buff er memory: this
stores the values of parameters that chan-
ge often, such as counters (if confi gured
in the application).
Mask description DescriptionUI MANAGEMENTActive UI: i/N Activate the set of screens, ‘i’ of ‘N’
Active trans: i/N Active translation ‘i’ of ‘N’
Prg to load next UI Press Prg to load the next set of screens
Ent to load next trans
Press Enter to load the next application
language
Mask description DescriptionBUILT IN SETTINGS Terminal settings: brightness, buzzer
Bklight idle val: xxx Backlighting intensity set after backlight
idle time.
Bklight idle time:xxx Time (s) before setting Bklight idle val.
Function disable if equal to 0.
Buzzer is off/on Buzzer status
Auto off time is off Built-In terminal auto backlighting off
Confirm value? No/yes Confi rm update
UPGRADE
Mask description Description> xxx.ap1 With the USB fl ash drive plugged into the host
USB port: .ap1 fi le contained in the Upgrade
directory on the drive.
With the USB fl ash drive not plugged in: .ap1 fi le
in the NAND1 partition (90 Mbytes).
LOGGER
Mask description DescriptionEXPORT LOGS Export the logger fi les
RESTART LOGS For periodical logs activated/terminated by
variable, start logging again.
FLUSH LOGS Save the logs to memory. Logs: max 32, max 4
Mbytes in binary format
WIPE LOGS Delete all the data and restart logging from the
beginning
DIAGNOSTICS
Mask description DescriptionSYSTEM LOGS Export the system log for diagnostics as a .zip fi le
SETTINGS
PASSWORD:PASSWORD:
Mask description Descriptioninsert new password00000Update password?
Password to prevent access to all the
pages of the tree menu, except for PCO
INFORMATION. To cancel the password,
set it to 00000.
USB SETTINGSUSB SETTINGS
Mask description DescriptionUSB HOSTPen drive:
Enable/disable
Enable/disable the Host/ Device USB
ports. Only use one port at a time, host
or device
USB DEVICE
PC connection: Enable/disable
Enable/disable the c.pCO controller as a
serial port for c.suite
pCO disk: Enable/disable
Enable/disable the c.pCO controller as a
storage device
Status (host/device): not connected/wait / ready
Connection status:
Not connected: peripheral not connected
Wait: connecting
Ready: peripheral ready to be used
PLAN SETTINGS:PLAN SETTINGS:
Mask description DescriptionpLAN pCO Addr: x Address of the c.pCO controller that the
terminal is currently connected to
Release term: No Release command
Acquire term: No Acquire command
Update config: No Confi rm update
CLOCK SETTINGS:CLOCK SETTINGS:
Mask description DescriptionDATE/TIME Date and time settings
Date: xxxx/xx/xx Date setting
Time: xx:xx:xx Time setting
DST is off/on Information on Daylight Saving Time
Update date/time ? Confi rm update
TIME SYNC Time synchronisation setting
Clock sync: xxx Synchronisation setting: manual, via
tERA or via NTP.
Update Config? Confi rm update
TIME ZONE Display the time zone
TCP/IP SETTINGS:TCP/IP SETTINGS:
Mask description DescriptionDHCP: Off/On Static/dynamic address
IP: xxx.xxx.x.x IP address
MASK: xxx.xxx.xxx.x Net mask
Gateway: x.x.x.x Gateway
DNS: x.x.x.x DNS
Name Host name, only changeable from c.suite
Update config? No/Si Update settings
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8. PROTECTION: PASSWORD AND DIGITAL SIGNATURE MANAGEMENT
The c.pCO controller implements protection methods aimed at
preventing unauthorised personnel from performing certain sensitive
operations like updating the software, accessing the system menu,
cloning proprietary software, etc.
It is possible to protect the c.pCO controller by setting a password or
a digital signature. Signing the controller by digital signature is an
irreversible process, while the password can be modifi ed or cancelled.
The password is applied by default in the c.suite development tool, while
the digital signature is an additional function enabled with a dedicated
license.
8.1 Protection features
Protection password Digital signaturePurpose To prevent the software being loaded/updated
by unauthorised personnel. To prevent the
software from being cloned.c.pCO signing Reversible IrreversibleGeneration By c.suiteActivation Function included
in standard c.suite
package
Function to be activated
with optional additional
licenseNumber of
passwors/signatures
c.suite software can be used to generate
multiple signatures and/or passwordsImplementation The application is
protected with a
password before being
uploaded into the
c.pCO (see paragraph
6.6 for uploading
procedures)
c.pCO is signed by
uploading a digital
signature via USB fl ash
drive. The application
to be uploaded must be
protected with the same
signature.
Tab. 8.a
8.2 Protection Password The protection password can be set inside the c.design tool, under
"c.pCO Confi guration Editor". A protection password can be set for each
confi guration. The protection password has no eff ect if using a digital
signature.
To set the protection password, proceed as follows:
1. Open c.design and select or create a new confi guration. Click
“c.pCO Confi g Editor”:
Fig. 8.a
2. Select the "Protection" tab:
Fig. 8.b
3. Enter the desired password to protect the controller-application (up
to 8 alphanumeric characters).
Note: • To modify the protection password for a confi guration, fi ll the
"Previous Password" fi eld and enter a new password in the
"Password" fi eld.
• To cancel the protection password for a confi guration, fi ll the
"Previous Password" fi eld and leave the "Password" fi eld empty.
4. Click “Save”. The Upload page will be displayed. Open c.factory by
clicking "Upload to Device".
Fig. 8.c
5. From the options fl ag "c.pCO Confi guration Editor" and select proper
type of connection.
Note: all the sections of "c.pCO Confi guration Editor" need to be
correctly fi lled (Network, pLAN, Users, Servers, Protection).
Fig. 8.d
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
6. Upload the signed application. If performing the operation on a
controller that already contains a protected application, the previous
protection password needs to be entered (see the fi gure below).
Fig. 8.e
Note: if loading an application program signed with the same
password, the password does not need to be entered again.
7. A status screen shows the progress of the upload; at the end, click OK
and “Close” to close “C.factory”
Fig. 8.f
Note: to complete activation of the protection password, power
the controller off and on again.
8.3 Digital signature generationProtection system by digital signature, if enabled by optional license,
prevents the programmable controller from being overwritten with
unauthorised software.
The controller is indelibly signed, with the password defi ned in c.design
tool. After a controller has been signed with a specifi c digital signature, it
can only be used with applications signed with the same digital signature
(see paragraph 8.4), and the digital signature applied cannot be erased
or modifi ed.
To sign a c.pCO with a digital signature, proceed as follows:
1. Open c.design and select or create a new confi guration. Click
“c.pCO Confi g Editor”:
Fig. 8.g
2. Select the "Protection" tab:
Fig. 8.h
3. Flag "Digital Signature", and insert password corresponding to the
new digital signature to be generated (8 alphanumeric characters).
Then click save.
Notes: • Digital signature option is shown only if "Digital Signature" license has
been activated.
• To modify the password of a digital signature, fi ll the "Previous
Password" fi eld and enter a new password in the "Password" fi eld.
• To remove the digital signature from a confi guration, fi ll the "Previous
Password" fi eld and leave the "Password" fi eld empty.
4. Click “Save”. The Upload page will be displayed. Open c.factory by
clicking "Upload to Device".
Fig. 8.i
5. Click “Generate Signature”: a screen is shown for selecting the path
where to save the digital signature fi le. Name and save the .ap1 fi le in
a directory called “UPGRADE” on a USB fl ash drive.
Fig. 8.j
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6. To load the digital signature to the controller:
• plug the USB fl ash drive into the host USB port.
• press Alarm and Enter together to enter the system menu;
• select “Upgrade” and confi rm by pressing Enter; the controller is
indelibly signed with the digital signature, it can only be used with
applications signed with the same digital signature (see par. 8.4).
USB key
USB connectorfrom computer
A
B
Fig. 8.k
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
Note: to complete activation of the digital signature, power the
controller off and on again.
Warning: digital signature cannot be erased once applied.
8.4 Loading an application program on a
controller signed with digital signatureA c.pCO controller signed with a Digital Signature can be used only
with an application software signed with the same signature. In order to
generate an application signed with Digital SIgnature, it is necessary to
follow the procedure described in the previous paragraph and proceed
with the installation of the application as described in paragraph 6.6.
If the digital signature for the application program being loaded on the
c.pCO does not correspond to the digital signature on the controller,
when loading the application program by using c.factory tool, a screen
is displayed prompting for the password corresponding to the digital
signature currently loaded on the c.pCO.
If the password entered is correct, the program will be uploaded correctly.
Note: if both a protection password and a digital signature have
been set on a c.pCO, the latter has priority.
8.5 System menu passwordSystem menu password prevents access to the system menu, except for
the information screen (“PCO INFORMATION", see paragraph 7.1).
Procedure:
1. Press Alarm and Enter together for 3 seconds to enter the system
menu;
2. Select Settings --> Password
3. Press Enter; set a value > 000000 using UP/DOWN.
4. Confi rm the changes.
INFORMATIONSETTINGSAPPLICATIONUPGRADELOGGERDIAGNOSTICS
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
PASSWORD USB SETTINGS PLAN SETTINGS DATE/TIME TCP/IP SETTINGS
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
INSERT NEW PASSWORD
00000
Update password:no/yes
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9. ACCESS MANAGEMENT FOR IP SERVICES
c.pCO controllers integrate a Web Server and a FTP Server:
• Web server: used to access the fi les (HTML pages, images, JavaScript
code, etc.) stored under the /HTTP/ directory of the public partition in
the fi le system. These pages can show dynamic contents generated
by CGI calls (Common Gateway Interface), managed by the controller
fi rmware in order to read/write variables of the application and create
logs and custom dynamic pages. These pages are accessed in a LAN by
using a browser, entering the c.pCO controller IP address or hostname;
• FTP server: used to access the public partition in the fi le system, to
read, edit, create and delete fi les and directories, including web pages.
FTP can also be used to transfer a .ap1 fi le, for example, to update the
image of the operating system or the application program. The fi les are
accessed using an FTP client, such as “FileZilla”.
For protecting the contents of the public fi le system against unauthorised
access, the system administrator can create diff erent users, and assign
each user diff erent access profi les, diff erentiated for each service and
adapted to the individual directory.
Access confi guration is performed in two steps
1. create users in c.design;
2. create authorisation fi les in the directories of the public fi le system
that need to be protected.
9.1 Accounts managementc.pCO does not have any account confi gured by default, consequently
the entire public fi le system has read/write access to the default user
(“anonymous”) and web access without authentication. This simplifi es
the operations for fi rst installation of the application program and web
pages via FTP/HTTP protocol. Subsequently, accounts can be created
so as to restrict access to the public fi le system. The accounts who can
access the IP services are created in c.design. Open c.design and access
the confi guration editor.
Fig. 9.a
Click “c.pCO Confi g. Editor”: the user confi guration page will be shown.
Enter the user name and password and confi rm by clicking “Add user” for
each new user.
Fig. 9.b
Example: the following three users have been created:
User name Passworddave davepasswd
bryan bryanpasswd
ron ronpasswd
Select the directory where the application program fi les are located and
click “Upload” to load these accounts into the c.pCO controller.
Note:• max number of users: 5;
• max number of characters in the user name: 15;
• max number of characters in the password: 15;
• in addition to the users saved in the database, the FTP server retains
the default user, called “anonymous”. This special user allows public
access to certain directories and to new c.pCO controllers without any
users confi gured. The anonymous user does not require authentication
(any password can be entered) and access will be restricted to the
directories that have no authorisation fi les (ftaccess, as illustrated
below).
The authorisation fi les contain a list of users who can access the current
directory. Only the users listed in the authorisation fi le can access the
corresponding directory.
Note: an authorisation fi le only prevents access to the fi les in the
directory where this is located, and not the fi les in any sub-directories. To
disable access to the various sub-directories, the authorisation fi le needs
to be copied to each of these.
The authorisation fi le is a simple text fi le, called:
• “htaccess”, when it authorises users of web server services;
• “ftaccess”, when it authorises users of FTP server services.
Authorisation fi le structure
The authorisation fi le contains a list of user names who are authorised to
access the directory in question, one on each line. There is no extension
(e.g. ".txt”).
Example: the authorisation fi le for the three users created previously will
have the following layout, and be called “ftaccess” or “htaccess”.
ftaccess/htaccessdave
bryan
ron
Whenever a user needs to access a fi le (web) or directory (FTP), the
following procedure is applied to grant/deny access:
1. verify whether the authorisation fi le (htaccess or ftaccess) exists in the
requested directory. If no fi le exists, access is granted;
2. if the fi le exists, this is opened and read sequentially to check whether the
user making the request is included in the list; if not, access is denied;
3. if the user is included in the authorisation fi le, the system looks up the
user name in the user database. If not found, access is denied;
4. if the user is known, authentication by password is required; if the
password is correct, access is granted.
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
Authorization file present
in directory ?
Is the user present in the
access file ?
Denyaccess
Access requestfor user to directory
YES
NO
YES
YES
NO
NO
NO
Is the user present in the system-level
user database?
Passwordcorrect?
Grantaccess
YES
Fig. 9.c
9.2 Computer - c.pCO connectionThere are two ways to connect the c.pCO controller to a computer via
Ethernet:
1. computer-c.pCO direct connection;
2. network LAN connection with DHCP server
Computer-c.pCO direct connection
Connect one end of the network cable to the Ethernet port on the
computer and the other end to a any of the Ethernet ports on the
c.pCO; LEDs blinking indicate correct connection. The Ethernet ports on
the c.pCO are auto-crossing (Auto MDI-X), therefore no crossover cable
is needed. After connection through Ethernet cable, computer and
controller IP addresses must be properly confi gure in order to belong to
the same IP subnetwork.
Confi guration example:
Computer:IP address: 192.168.0.2
Subnet mask: 255.255.255.0
c.pCO controller: 1. press Alarm and Enter together for 3 seconds to access the system
menu;
2. Select Settings -->TCP/IP settings: DHCP = OFF and enter an address
in the same subnet set on the PC, for example:
IP: 192.168.0.1
MASK: 255.255.255.0
3. Select update confi guration --> Yes
INFORMATIONSETTINGSAPPLICATIONUPGRADELOGGER
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
PASSWORD USB SETTINGS PLAN SETTINGS DATE/TIME TCP/IP SETTINGS
INFORMATION SETTINGS APPLICATION UPGRADE LOGGER DIAGNOSTICS
DHCP: OffIP: 192. 168. 0. 1MASK: 255. 255. 255. 0GW: 0. 0. 0. 0DNS: 0. 0. 0. 0NAME:Update config? Yes
Network LAN connection with DHCP server
Before connecting the c.pCO controller to the LAN, access the system
menu and verify that DHCP: On (default setting).
Then connect the c.pCO to the LAN. The IP address is automatically
assigned to the c.pCO by the DHCP server, and it can be displayed in the
system screens (Settings -->TCP/IP settings).
9.3 FTP connection with authenticationOnce having connected the computer to the c.pCO via Ethernet, FTP
protocol can be used to transfer fi les. The program used in this example is
“FileZilla”, downloadable for free from the Internet.
Proceed as follows:
1. open FileZilla: the following screen will be shown;
2. enter the IP address (or hostname) of the c.pCO controller, the user
name --> anonymous and password -->“empty” and select “Quick
Connect”;
3. the user can access all the directories highlighted, as these do not
contain the “ftaccess” fi le: UPGRADE, HTTP. Access is also available to
the HTTP directory and its sub-directories.
Nota: Please use following settings in Filezilla:
• Edit->Settings->Connection-> set timeout in seconds = 0
• Edit -> Settings -> Transfers -> set maximous simultaneous transfers to 1
Fig. 9.d
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
Access to the diff erent directories can be restricted, assigning diff erent
user lists (see paragraph 9.1).
Important: in the event of errors when copying the authorisation
fi les and consequently denial of access, the authorisation fi les can only be
deleted by direct connection to the USB device port.
9.4 HTTP connection with authenticationThis paragraph shows how to restrict access to the web interface or
part of it. In the example, a website is created with several pages in “\
HTTP”, administration pages in “\HTTP\admin” and user pages in “\HTTP\
user”. Only “dave” and “ron” can access the administration pages, while
the user pages are only accessible to “bryan”. All three users can see the
common pages in “\HTTP”. The authorisation fi les shown in the table
need to be created and copied by FTP to the corresponding directories
(see paragraph 9.1):
No. Authorisation fi le In directory User Password
1 htaccess HTTP dave davepasswd
bryan bryanpasswd
ron ronpasswd
2 htaccess HTTP\admin dave davepasswd
ron ronpasswd
3 htaccess HTTP\user bryan bryanpasswd
Accessing an address of the c.pCO Web Server by using a web browser,
then a pop-up window will be shown prompting for the user name and
password.
Fig. 9.e
If the user name/password are recognised and the user has been
authorised to access the directory, for example “dave”, the web server
grants access to the pages, and these can be displayed by the browser.
Fig. 9.f
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10. WEB SERVER AND TERA CLOUD PLATFORM
c.pCO controllers family features an integrated web server that can be
completely customised by the user. The c.pCO web server can support HTML
and JavaScript standards. Custom web pages can be copied in the public
fi le system, in the /HTTP/directory. c.pCO implements some CGI (Common
Gateway Interface) scripts that allow to dynamically read and write application
variables in order to create dynamic content. A freely customisable package
called “Web kit” is available to simplify the creation of custom webpages for
the c.pCO. The Web kit comprises sample HTML pages and JavaScript libraries
for managing dynamic CGI, fully exploiting the potential of the c.pCO web
server. In particular, the examples provided can be used to:
1. display the contents of the pGD1 on the browser pages (pGDWeb,
see paragrap 10.3)
2. display the list of public variables in the application program, allowing
the values to be read and write;
3. display the network status, with the addresses of the connected
devices;
4. plot data on graphs, both in real time as well as extracted from
logged data.
10.1 Web kit download and installationThe freely customisable web package called “Web kit” can be downloaded in
ksa.carel.com. The package must be saved in the c.pCO public fi le system:
1. unzip the .zip fi le;
2. copy the contents to the /HTTP/ directory in the c.pCO fi le system by
using the USB device port or FTP protocol through Ethernet (see picture
below).
3. Disconnect Usb cable from USB device port.
Fig. 10.a
4. After copy of the Web kit package into folder /HTTP/, it is possible to
access web pages by using a web browser. It is suffi cient to connect
the c.pCO and the computer in the same local network and write in
the browser address bar the c.pCO IP address (see paragraph 9.2).
The web pages are independent from application software loaded into
the controller, and they are developed to be customized according to the
specifi c application.
Fig. 10.b
10.2 Contents of the package
Directory Sub-directory Contentsimgs Images used by all the pages
lib File libraries: CSS (Cascaded Style Sheet) and
JavaScript for dynamic variable handling, graphs
from logs and graphs in real time. Default CSS
fi le (optimised for browser with 1024 pixel
resolution)calendar Graphic elements (calendar) used by the log
pages jscolor Graphic elements (color picker) used by the log
pagespgd pGD web interface: do not delete or remove fi les
from here. Index.html can be customised, so as to
change the pGD eeb screen.imgs Image fi les used by the pGD web interface: do
not delete or remove fi les from herefavicon.ico Browser “favourite” icons, can be completely
customisedTab. 10.a
10.3 Web pGDThe virtual terminal shows the information displayed on the pGD terminal
connected to the c.pCO in real time.
2
1
3
4
Fig. 10.c
Key1 Active area (394 x 198 pixels)
2 Buttons that can be activated by clicking the mouse
3 Function to press multiple buttons
4 LEDs
Customisation notes: • The virtual pGD is a matrix of 132 x 64 elements measuring 3 x 3 pixels;
• The background for the LCD matrix measures 394 x 198 pixels;
• The background colour is black (RGB 0, 0, 0), the colour of the display is
light blue (RGB 106, 188, 231);
• The image of the pGD1 is 870 x 455, the background starts at (x, y =
238, 128) and ends at (x, y = 632, 326);
• The width of the buttons is 27%, the heights are 20%, 19%, 19%, 19%, 23%:
these proportions must be maintained to change the background image.
See the comments in: /pgd/index.htm for further details on customising
this page.
10.4 Variables tableThe variables table includes the public variables exposed by the
application soff tware. Names and descriptions are defi ned in c.suite
development enviroment.
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
1
2
3
Fig. 10.d
Key1 Frame: blue = communication, red = no communication
2 Variable refresh time
3 Checkbox to enable in order to write variables
Writing the variablesProcedure:
• enable the writing checking box;
• enter the value in the corresponding fi eld;
• click Set or “Set all selected variables”.
10.5 Variable trend (logger)The names of the logs are loaded dynamically by the c.pCO based on
the Log editor settings in c.design. This means the drop-down menu for
choosing the log to be displayed is populated automatically, without
having to modify the web page:
• choose the log to be displayed from the drop-down menu at the top;
• set the display interval, as start and end date/time or using the quick
links on the right, used to load the last ‘N’ days/weeks logged;
• click “Load log data” to load the log and display the corresponding
graph.
The graph can then be adapted using the mouse (or touch, when using
a touch screen) to zoom, change the colour of the lines, display the
numeric values of the variables at a certain point on the graph, or enable
the secondary axis.
A screenshot in image format can be saved at any time, or the data
exported in CSV format.
Fig. 10.e
Choosing the “Live” tab activates a real time graph of the variables, chosen
from the list of public variables.
• Click “Show/Hide variables” to show the variable list (automatically
populated by the c.pCO).
• Choose the variables to be displayed from the list
• Choose the sampling period (expressed in seconds) and the display
interval (expressed in minutes)
• Click “Play” to start acquiring the data
In this case too, the graph can be adapted, even during the acquisition
process.
Fig. 10.f
10.6 c.pCO connection to cloud tERAThe c.pCO controllers family can establish a remote secure connection
to the Carel cloud server platform called tERA. Every c.pCO with built-in
Ethernet interface is natively integrated into tERa cloud platform and can
access to linked services. Every c.pCO is uniquely identifi ed by the tERA
cloud using its MAC address. It is possible to create a customized private
portal according to the customers specifi cations. For further information
on tERA services available, contact your local Carel sales network.
Fig. 10.g
c.pCO registration:Activation and registration procedure and settings of the tERA services
are described in the "tERA Quick start Guide" (document +030222141),
that can be download from www.carel.com.
Following data are requested in order to register a c.pCO in tERA server:
• MAC address of the c.pCO
• c.pCO serial number (S/N)
• tERA password
Above data are reported in the c.pCO System menu at the following path:
INFORMATION --> pCO INFORMATION (see fi gure below).
BT v1.2.000 2014/02/12OS v1.2.000 2014/02/12SVN REV 2796MAC 00-0A-5C-40-03-2BS/N 000000000000032BtERA 5E2207C4
Fig. 10.h
c.pCO Update from tERAFrom tERA portal, it is possible to update the application program and
the Operating System of the c.pCO by remote. The controller should be
already registered in the tERA portal.
Procedure is described in "tERA Quick start Guide" (document
+030222141), that can be download from www.carel.com.
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11. EXAMPLES
The following are a series of diagrams illustrating which devices can be
connected to the c.pCO and the accessory cards required, depending on
the type of application.
Air handling unit
PCOS004850: scheda seriale RS485
PCO10000F0:schede LON
S90CONN*: cavo di
collegamento
sonde serialiDP****4****
PCO10W0BA0: scheda interfaccia BACnet™ RS485
PCO10W0WB0:pCO Web - sch. interfacciaEthernet™/BACnet™Servocontrollo
della serrandaValvola di
servocontrollo
PCO100MPB0:scheda MP-BUS
584SRsutats
GNX RS485+ –P1 P2 P3
BACnet™ MS/TP
PGD Touch
PGD1* CP*: schede controllo umidificatori KUE*
dispositiviterze parti
FAN
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7
J8
J20
J21
J14
J10
J13J12
J22
J16 J17 J18J15
J6
J19
NO
14 C14
NC1
4
NO
15 C15
NC1
5
C16
NO
16
NO
17
NO
18 C16
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
J23 FBus2
input: 24 V 50...60 Hz / 28...36 Vmax. power: 45 VA/20 W
J11 pLAN
J25 BMS2 J26 FBus2
4 3 2 1
Fig. 11.a
Roof-top unit
EEV
PCOS004850: scheda seriale RS485
PCO10000F0:schede LON
S90CONN*: cavo di
collegamento
sonde serialiDP****4****
PCO10W0BA0: scheda interfaccia BACnet™ RS485
PCO10W0WB0: pCO Web - sch. interfacciaEthernet™/BACnet™Servocontrollo
della serrandaValvola di
servocontrollo
PCO100MPB0:scheda MP-BUS
584SRsutats
GNX RS485+ –P1 P2 P3
BACnet™ MS/TP
PGD Touch
PGD1* CP*: schede controllo umidificatori KUE*
C1
NO
1
NO
2
NO
3
C1
C4
NO
4
NO
5
NO
6
C4
C7
NO
7
C7
NO
8
C8
NC
8
NO
12
C12
NC
12
NO
13
C13
NC
13C9
NO
9
NO
10
NO
11 C9
G G0
U1
u2 U3
GN
D
+VD
C
+Vt
erm
GN
D
+5
VREF
U4
GN
D
U5
GN
D
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1
U6
U7
U8
GN
D
ID9
ID10
ID11
ID12
IDC
9
ID13
H
ID13
IDC
13
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J14
J10
J13J12 J16 J17 J18J15
J6
Fie ldBus card B M S cardinput: 24 V 50...60 Hz / 28...36 Vmax. power: 45 VA/20 W
J11 pLAN
J25 BMS2 J26 FBus2
OFF
4 3 2 1ON
4231
J127
GN
D
VREF
S1 S2 S3 S4 DI1
DI2
J29
VBA
T
G0 G
J30A B C D
Power +PSD0*
Fig. 11.b
Heat pump
S90CONN*: cavo di
collegamento
sonde serialiDP****4****
th TuneAT*
PCO100FD10:scheda serialeFieldBus
PGD TouchEEV
PGD1* Power +PSD0*
PCOS004850: scheda seriale RS485
PCO10000F0:schede LON
PCO10W0BA0: scheda interfaccia BACnet™ RS485
PCO10W0WB0: pCO Web - sch. interfacciaEthernet™/BACnet™
584SRsutats
GNX RS485+ –P1 P2 P3
BACnet™ MS/TP
C1
NO
1
NO
2
NO
3
C1
C4
NO
4
NO
5
NO
6
C4
C7
NO
7
C7
NO
8
C8
NC
8
NO
12
C12
NC
12
NO
13
C13
NC
13C9
NO
9
NO
10
NO
11 C9
G G0
U1
u2 U3
GN
D
+VD
C
+Vt
erm
GN
D
+5
VREF
U4
GN
D
U5
GN
D
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1
U6
U7
U8
GN
D
ID9
ID10
ID11
ID12
IDC
9
ID13
H
ID13
IDC
13
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J14
J10
J13J12 J16 J17 J18J15
J6
Fie ldBus card B M S cardinput: 24 V 50...60 Hz / 28...36 Vmax. power: 45 VA/20 W
J11 pLAN
J25 BMS2 J26 FBus2
4 3 2 1
4231
J127
GN
D
VREF
S1 S2 S3 S4 DI1
DI2
J29
VBA
T
G0 G
J30A B C D
Fig. 11.c
Close control unit (CCU)
S90CONN*: cavo di
collegamento
PGD Touch
PGD1*
EEV
Power + PSD0*schede CP*: controllo umidificatori KUE*
dispositiviterze parti
FAN
PCOS004850: scheda seriale RS485
PCO10000F0:schede LON
PCO10W0BA0: scheda interfaccia BACnet™ RS485
PCO10W0WB0: pCO Web - sch. interfacciaEthernet™/BACnet™
584SRsutats
GNX RS485+ –P1 P2 P3
BACnet™ MS/TP
C1
NO
1
NO
2
NO
3
C1
C4
NO
4
NO
5
NO
6
C4
C7
NO
7
C7
NO
8
C8
NC
8
NO
12
C12
NC
12
NO
13
C13
NC
13C9
NO
9
NO
10
NO
11 C9
G G0
U1
u2 U3
GN
D
+VD
C
+Vt
erm
GN
D
+5
VREF
U4
GN
D
U5
GN
D
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC
1
U6
U7
U8
GN
D
ID9
ID10
ID11
ID12
IDC
9
ID13
H
ID13
IDC
13
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J14
J10
J13J12 J16 J17 J18J15
J6
Fie ldBus card B M S card
J11 pLAN
J25 BMS2 J26 FBus2
4 3 2 1
4231
J127
GN
D
VREF
S1 S2 S3 S4 DI1
DI2
J29
VBA
T
G0 G
J30A B C D
Fig. 11.d
57
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Chiller - Screw compressor
To manage two refrigerant circuits, there are two options.
Case 1: 2 c.pCO Medium controller and c.pCO Medium with built-in
electronic expansion valve driver.
S90C
ON
N*:
ca
vo d
i col
lega
men
to
PGD TouchPGD1*dispositiviterze parti
dispositiviterze parti
dispositiviterze parti
FAN PUMPINVERTER
PGD1*
EEV EEV
PCOS004850: scheda seriale RS485
PCO10000F0:schede LON
PCO10W0BA0: scheda interfaccia BACnet™ RS485
PCO10W0WB0: pCO Web - sch. interfacciaEthernet™/BACnet™
584SRsutats
GNX RS485+ –P1 P2 P3
BACnet™ MS/TP
PCOS004850: scheda seriale RS485
PCO10000F0:schede LON
PCO10W0BA0: scheda interfaccia BACnet™ RS485
PCO10W0WB0:pCO Web - sch. interfacciaEthernet™/BACnet™
584SRsutats
GNX RS485+ –P1 P2 P3
BACnet™ MS/TP
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
G G0 U1 u2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J14
J10
J13J12 J16 J17 J18J15
J6
Fie ldBus card BMS cardinput: 24 V 50...60 Hz / 28...36 Vmax. power: 45 VA/20 W
J11 pLAN
J25 BMS2 J26 FBus2
OFF
4 3 2 1ON
4231
J127
4231
J128
GND
VREF
S1 S2 S3 S4 DI1
DI2
J29
VBAT
G0 G
J30A B C D
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
G G0 U1 u2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J14
J10
J13J12 J16 J17 J18J15
J6
Fie ldBus card BMS cardinput: 24 V 50...60 Hz / 28...36 Vmax. power: 45 VA/20 W
J11 pLAN
J25 BMS2 J26 FBus2
4 3 2 1
Case 2: 1 c.pCO Large with external EVD Evolution twin driver.
S90CONN*: cavo di
collegamento
PGD Touch
EVD*T*EVD Evolution twin EEV
EEV
dispositivi terze parti
FAN PUMPINVERTER
PCOS004850: scheda seriale RS485
PCO10000F0:schede LON
PCO10W0BA0: scheda interfaccia BACnet™ RS485
PCO10W0WB0: pCO Web - sch. interfacciaEthernet™/BACnet™
584SRsutats
GNX RS485+ –P1 P2 P3
BACnet™ MS/TP
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
G G0 U1 U2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7
J8
J20
J21
J14
J10
J13J12
J22
J16 J17 J18J15
J6
J19
NO
14 C14
NC1
4
NO
15 C15
NC1
5
C16
NO
16
NO
17
NO
18 C16
ID15
H
ID15
IDC1
5
ID16
ID16
H
Y5 Y6 ID17
ID18
IDC1
7
U9 GND
U10
GNDFie ldBus card BMS card
J23 FBus2
J11 pLAN
J25 BMS2 J26 FBus2
4 3 2 1
Chiller - Scroll compressor
S90CONN*: cavo di
collegamento
PGD Touch EEV
PGD1*
FAN PUMPINVERTER
dispositivi terze parti
PCOS004850: scheda seriale RS485
PCO10000F0:schede LON
PCO10W0BA0: scheda interfaccia BACnet™ RS485
PCO10W0WB0: pCO Web - sch. interfacciaEthernet™/BACnet™
584SRsutats
GNX RS485+ –P1 P2 P3
BACnet™ MS/TP
C1
NO
1
NO
2
NO
3 C1 C4
NO
4
NO
5
NO
6 C4 C7
NO
7 C7
NO
8 C8
NC8
NO
12 C12
NC1
2
NO
13 C13
NC1
3C9
NO
9
NO
10
NO
11 C9
G G0 U1 u2 U3 GN
D
+VDC
+Vte
rm
GN
D
+5 V
REF
U4 GND
U5 GND
VG VG0
Y1 Y2 Y3 Y4 ID1
ID2
ID3
ID4
ID5
ID6
ID7
ID8
IDC1
U6 U7 U8 GN
D
ID9
ID10
ID11
ID12
IDC9
ID13
H
ID13
IDC1
3
ID14
ID14
H
J1 J24 J2 J3 J4 J5 J7 J8
J14
J10
J13J12 J16 J17 J18J15
J6
Fie ldBus card BMS card
J11 pLAN
J25 BMS2 J26 FBus2
4 3 2 14231
J127GN
D
VREF
S1 S2 S3 S4 DI1
DI2
J29
VBAT
G0 G
J30A B C D
58
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
11.1 Devices that can be connected to the c.pCO
Device seriale zero - pLAN o display port seriale uno - BMS1 seriale due
– FBus 1seriale tre -
BMS 2seriale quattro -
FBus 2 USB Master
(Host) USB Slave
(Device) Ethernet
con
ne
cto
r J1
1
con
ne
cto
r J1
0
con
ne
cto
r
J3 D
isp
.
PC
OS
00
48
50
PC
O1
00
00
F0
PC
O1
0W
0W
B0
PC
O1
0W
0B
A0
PC
OS
00
KX
B0
PC
O1
00
FD
10
PC
OS
00
KX
F0
con
ne
cto
r J2
5
con
ne
cto
r J6
BM
S
con
ne
cto
r J2
6(a
nd
J2
3 s
u L
- X
L)
con
ne
cto
r J4
FB
us
pGD1 terminal x xPCOT - pCOI terminal
(pGD1 version only)x x
pLDPRO terminal x xEVD Evolution x x xCAREL Slave devices (485) x x xpCOexp 485 x x xc.pCOe x x xPlantVisorPRO x x x x x x x xPlantWatchPRO x x x x x x x xPCGate x x x x x x x xWebGate x x x x x x x xGATEWAY**0 x x x x x x x xLON - Echelon FTT10 xBACnet/MSTP (RS485) xKonnex x xHTTP client x xBACnet/Ethernet xBACnet/IP x xSNMP v1, SNMP v2C xModbus TCP/IP x xModbus supervisor (RTU) x x x x xModbus Slave devices x x xPower + x x xPendrive (USB fl ash drive ) xPC Mass Storage xth-Tune terminal x x xpGD Touch x x x x x x x
Tab. 11.a
12. TECHNICAL SPECIFICATIONS
12.1 c.pCO technical specifi cations
Physical specifi cations
Dimensions
MINI panel 147.3 x 81.3 x 70.5 mm4 DIN modules 70 x 110 x 63 mm
SMALL 13 DIN modules 110 x 227,5 x 60 mm
MEDIUM, LARGE, EXTRALARGE 18 DIN modules 110 x 315 x 60 mm
BUILT-IN DRIVER 18 DIN modules 110 x 315 x 75 mm
Plastic case
Assembly on DIN rail in accordance with DIN 43880 and IEC EN 50022 / or panel
Material technopolymer
Flammability V2 (UL94) and 850 °C (in accordance with IEC 60695)
Ball pressure test temperature 125 °C
Resistance to creeping current ≥ 250 V
Colour White RAL 9016
Built-in terminal PGD1 (132x64 pixel) with backlit keypad
Other specifi cations
Operating conditions c.pCO: P+5**SE***0** (w/o built-in terminal): -40T70 °C, 90% RH non-condensing(*)
c.pCOmini: P+(D)*******0** (w/o built-in terminal): -40T70 °C, 90% RH non-cond.c.pCO:P+5**SE***E** (with built-in term.): -20T60 °C, 90% RH non-condensing
c.pCOmini: P+(D,P)*******E** (with built-in term.): -20T60 °C, 90% RH non-cond.(*) with Ultracap module fi tted: -40T60°C
Storage conditions
c.pCO: P+5**SE***0** (w/o built-in terminal): -40T70 °C, 90% RH non-condensing
c.pCOmini: P+(D)*******0** (w/o built-in terminal): -40T70 °C, 90% RH non-cond.c.pCO: P+5**SE***E** (with built-in terminal): -30T70 °C, 90% RH non-cond.
c.pCOmini: P+(D,P)*******E** (with built-in terminal): -30T70 °C, 90% RH non-cond.
Ingress protection
c.pCO: models with USB port and/or with Ultracap module: IP20 on the front panel only
Models without USB port and without Ultracap module: IP40 on the front panel only
c.pCOmini: P+P********** (panel): IP 65; P+D********** (DIN): IP 40Controller pollution class 2
Class according to protection against electric
shock
c.pCO: to be integrated into Class I and/or II equipment in versions without valve driver, Class I in versions with
valve driver
c.pCOmini: to be integrated into Class I and/or II equipment (Basic/Enhanced) - Class I (High-End)
PTI of insulating materials PCB: PTI 250 V; insulating material: PTI 175
Period of electrical stress across the insulating parts long
Type of action 1C; 1Y for SSR versions
Type of disconnection or microswitching microswitching
59
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Heat and fi re resistance category Category D (UL94-V2)
Ageing characteristics (operating hours) 80,000
No. of automatic operating cycles 100,000 (EN 60730-1); 30,000 (UL60730)
Rated impulse voltage c.pCO: 2500V
Electrical specifi cationsPower supply
MINI, SMALL, MEDIUM, LARGE, EXTRALARGE: use a dedicated class II 50 VA safety transformer.
BUILT IN DRIVER: use a dedicated class II 100 VA safety transformer..
Vac P (Vac) Vdc P (Vdc)MINI
24 Vac (+10/-15%), 50/60
Hz to be protected by 2.5 A
T external fuse
30 VA (40 VA with Ultracap module)
28 to 36 Vdc (-20/+10%)
to be protected by 2.5 A T external fuse
12 WSMALL
45 VA 30 WMEDIUMLARGEEXTRALARGEBUILT-IN DRIVER 90 VA Not allowed
Important: the c.pCO with built-in driver must be powered with alternating current and the secondary winding of the power supply transformer (G0) must
be earthed; if the Ethernet connection is used, the transformer secondary winding (G0) must be earthed.
Terminal block with plug-in male/female connectorsCable cross-section min 0.5 mm2 - max 2.5 mm2CPU 32 bit, 100 MHzNon-volatile memory (FLASH) 128 Mbyte of which 90Mbyte available as File storageData memory (RAM) 16 MbytesRetain memory 31744 bytesWorking cycle duration (application of average complexity) 0.2 s (typical)Clock with battery standard, precision: c.pCO/c.pCOmini: 100/ 50 ppmBuzzer can be software-enabled only via built-in terminalBattery c.pCO: 3 Vdc lithium button battery (24x3 mm), code CR2430
c.pCO 3 Vdc lithium button battery (20x3.2 mm), code BR2032Software class and structure Class ACategory of immunity to voltage surges (EN 61000-4-5) c.pcO / c.pCOmini: Category III/IIDevice not designed to be hand-held when powered
Universal inputs/outputs U...
Analog inputs, Lmax = 30 m (max. number)MINI SMALL MEDIUM / BUILT-IN DRIVER / EXTRALARGE LARGE
NTC CAREL probes (-50T90°C; R/T 10 kΩ±1% a 25°C);
NTC HT (0T150°C);
PTC (600Ω ...2200Ω)
PT500 (-100T300°C)
PT1000 (-100T400°C)
10 5 8 10
PT100 probes (-100T400°C); 5 2 3 (2 su U1...U5, 1 su U6...U8) 4 (2 su U1...U5, 1 su U6...U8, 1 su U9...U10)
0...1 Vdc/0...10 Vdc signals from probes powered by the
controller(*)-
max
to
t 5
5
max
to
t 8
6
max
to
t 1
0
6
0...1 Vdc/0...10 Vdc signals from probes powered extern. (*) 10 5 8 10
0...20 mA /4...20 mA inputs from probes powered by the
controller(*)
max
to
t 4
2
max
to
t 4
4
max
to
t 7
6 (max 4 su U1...U5, 3 su U6...U8)
max
to
t 9
6 (max 4 su U1...U5, 3 su U6...U8, 2 su U9...U10)
0...20 mA /4...20 mA inputs from probes powered extern. (*) 4 4 7 (max 4 su U1...U5, 3 su U6...U8) 9 (max 4 su U1...U5, 3 su U6...U8, 2 su U9...U10)0...5 V signals from ratiometric probes powered by the
controller (*)2 5 6 6
Input accuracy: ± 0,3 % f.s.Time constant for each input: 0,5 sClassifi cation of measuring circuits (CEI EN 61010-1): category I
Non optically isolated digital inputs
MINI SMALL MEDIUM / BUILT-IN DRIVER / EXTRALARGE LARGE
Lmax 30 m 30 m 30 m 30 m
voltage-free contacts 10 5 8 10fast digital inputs : Type: voltage-free contacts; Max. current:
10 mA; Max. frequency 2kHz and resolution ±1 Hzmax 2 max 2 4 (max 2 su U1...U5, max 2 su U6...U8)
6 (max 2 su U1...U5, max 2 su U6...U8, 2 su U9...
U10)
Warning:• To avoid irreparably damaging the controller, externally powered active probes (0...1 V, 0...10V, 0...20 mA, 4...20 mA) should be provided with adequate current
protection and the current should be < 100 mA
• Ratiometric probes can be powered by the controller only.
• At power on, universal inputs/outputs are short circuited to GND for about 500ms up to the end of the confi guration.
MINI SMALL MEDIUM/ BUILT-IN DRIVER/EXTRALARGE LARGE
0 to 10 Vdc (*) (max. current 2 mA) 5 5 8 10• PWM (0/3.3 Vdc output, max. current 2 mA, frequency: 2kHz asynchronous,
100 Hz asynchronous)
• c.pCOmini: PWM (0/10 Vdc output, 10 mA max. current. Frequency: 2 kHz
synchronous, 100 Hz asynchronous). Duty Cycle set by application software in
the range: 0% - 10%...90% - 100%
10 5 8 10
60
ENG
c.pCO +0300057EN rel. 1.0 - 19.01.2015
Power supply for probes and terminals
+Vdc
c.pCO: Active probes can be powered by the 24/21 Vdc ±10% available on terminal +VDC (J2). The max. available current is 150 mA, protected against
short-circuits.
c.pCOmini: 12 Vdc ± 8%; maximum current is 50 mA, protected against short-circuits.
+5Vrefc.pCO: To power the 0 to 5 V ratiometric probes use the 5 Vdc (±5%) available on terminal +5VREF(J24). The max. available current is 60mA.
c.pCOmini: +5VREF = 5 Vdc ± 3%; maximum current is 50 mA, protected against short-circuits.
Vterm
c.pCO: 24 Vdc ± 10%
To be used to power an external terminal in alternative to the one connected to J10, Pmax = 1.5 W - Warning: For lengths greater than 10 m use a shielded
cable with earthed shield. In any case the max. allowable length is 30 m. c.pCOmini: 24...36 Vdc ± 5% depending of power supply; max available current:
100 mA (pGD1, pLDPRO, thTUNE CAREL), protected against short-circuits. Maximum cable length: 10 m.
Digital inputs ID... IDH
Type c.pCO Small...Extralarge optically-isolated; c.pCOmini not optically-isolated
Lmax 30 m, (c.pCOmini 10m)
Voltage-free contactsno. of optically-isolated inputs at 24
Vac or 24 Vdc
no. of optically-isolated inputs at 24 Vac/
Vdc or 230 Vac - 50/60 Hz
Maximum
number
MINI (only Enhanced/HighEnd) 2 0 0
SMALL 0 8 0
MEDIUM/ BUILT-IN DRIVER/EXTRALARGE 0 12 2
LARGE 0 14 4
Minimum digital input pulse detection timeNormally open (open-closed-open): 200 ms;
Normally closed (closed-open-closed): 400 ms;
Power supply to inputs
c.pCO Small...Extralarge - External
c.pCOmini - InternalIDH...: 230 Vac (+10/-15%) 50/60 Hz
ID...: 24 Vac (+10/-15%) 50/60 Hz or 28-36 Vdc (+10/-20%)
Classifi cation of measuring circuits (EN 61010-1)Category I: 24 Vac/Vdc (J5, J7, J20)
Category III: 230 Vac (J8, J19)Digital input current draw at 24 Vac/Vdc 5 mA
Digital input current draw at 230 Vac 5 mA
Important:c.pCO SMALL, MEDIUM, BUILT-IN DRIVER, LARGE, EXTRALARGE: • separate as much as possible the probe and digital input cables from cables to inductive loads and power cables, so as to avoid possible electromagnetic
disturbance. Never run power cables (including the electrical panel cables) and signal cables in the same conduits;
• the two 230 Vac or 24 Vac/Vdc inputs on terminals J8 (ID13, ID14) or J19 (ID15, ID16) have the same common pole and must therefore be powered at the same voltage
(230 Vac or 24 Vac/Vdc). There is functional insulation between the two inputs; there is reinforced insulation between the inputs and the rest of the controller;
• ID1...ID8, ID9 to ID12, ID17, ID18 have functional insulation from the rest of the controller;
• for DC voltage inputs (24 Vdc) either the + or the - can be connected to common terminal;
• the rating of the external contact connected to the digital inputs must be at least 5 mA.
c.pCOmini• separate as much as possible the probe and digital input cables from cables to inductive loads and power cables, so as to avoid possible electromagnetic
disturbance. Never run power cables (including the electrical panel cables) and signal cables in the same conduits;
• the rating of the external contact connected to the digital inputs must be at least 5 mA.
Analogue outputs Y...
MINI SMALL MEDIUM / BUILT-IN DRIVER / EXTRALARGE LARGEType 0...10 V no optically-isolated, su Y1, Y2 0...10 V optically-isolated on Y1...Y6Lmax 10m 30 mMaximum number 2: Y1, Y2 4: Y1...Y4 a 0...10 V 6: Y1...Y6 a 0...10 VPower supply Internal external: 24 Vac (+10/-15%) o 28...36 Vdc su VG(+), VG0(-) (*)Precision Y1, Y2 ± 3% full scale Y1...Y6: ± 2% full scaleResolution 8 bit 8 bitSettling time Y1,Y2: da 1 s (slew rate 10 V/s) a 20 s (slew
rate 0,5 V/s) selectable via SWY1...Y6: da 1 s (slew rate 10 V/s) a 20 s (slew rate 0,5 V/s) selezionabile via SW
Maximum load 1 kΩ (10 mA) 1 kΩ (10 mA)
Warnings - c.pCO SMALL, MEDIUM, BUILT-IN DRIVER, LARGE, EXTRALARGE• for lengths greater than 10 m use a shielded cable with earthed shield;
• a 0 to 10 Vdc analogue output can be connected in parallel to other outputs of the same kind, or alternatively to an external source of voltage. The higher voltage
will be considered. Correct operation is not guaranteed if actuators with voltage inputs are connected;
• power the VG-VG0 analogue outputs at the same voltage on G-G0: connect G to VG and G0 to VG0. This applies in case of both alternating or direct current power
supplies.
c.pCOmini• for lengths greater than 10 m use a shielded cable with earthed shield;
• a 0 to 10 Vdc analogue output can be connected in parallel to other outputs of the same kind, or alternatively to an external source of voltage. The higher voltage
will be considered. Correct operation is not guaranteed if actuators with voltage inputs are connected;
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
Digital outputs NO..., NC...
c.pCOminiMaximum connection cable length: less than 30 mType Relay.Maximum no. 6
Insulation distanceThe outputs can be divided into groups: between group 1 and 2 there is basic insulation. Group 3 has reinforced insulation from
the fi rst 2 groups and can be powered at a diff erent voltage.Relays with same insulation Group
Composition of groups Model 1 2 3MINI 1...2 3, 4, 5 6Type of relay Type C Type C Type D
Number of changeover contacts 1 (relay 6)Switchable power Type C Relay rating
Approval NO EN 60730-1: 2(1)A (75000 cycles)
UL 60730:5 A resistive, 250 Vac, 30000 cycles, 105 °C. Defi ned purpose, 1FLA, 6LRA,
250 Vac, 30000 cycles, 105 °C, pilot duty C300, 250 Vac, 30000 cycles, 105 °CType D Relay rating
Approval NO EN 60730-1: 1(1)A (100000 cycles), maximum switchable voltage: 250 VacUL 60730-1: 1 A resistive, 1 A FLA, 6 A LRA, 250 Vac, D300 pilot duty, 30000 cycles
R2, R5 with SSR assembly: switchable power 15 VA 110/230 Vac or 15 VA 24 Vac according to the model purchased
c.pCO SMALL, MEDIUM, BUILT-IN DRIVER, LARGE, EXTRALARGEType Relay. Min. contact current: 50 mA.
Maximum no. 8: SMALL; 13: MEDIUM/ BUILT-IN DRIVER; 18: LARGE; 29: EXTRALARGE
Insulation distance
The relay outputs have diff erent features depending on the controller model. The outputs can be divided into groups. Relays belon-
ging to the same group (individual cell in the table) have operational insulation and must therefore be powered at the same voltage.
Between groups (between cells in the table) there is reinforced insulation, so the relays can be powered at diff erent voltages. There is
also reinforced insulation between each terminal of the digital outputs and the rest of the controller. Relays with same insulation
Group
Composition of groups
Model 1 2 3 4 5 6 7 8 9 10 11SMALL 1...3 4...6 7 8 - - - - - - -Type of relay Type A Type A Type A Type A - - - - - - -MEDIUM/ BUILT-IN DRIVER 1...3 4...6 7 8 9...11 12 13 - - - -Type of relay Type A Type A Type A Type A Type A Type A Type A - - - -LARGE NO 1...3 4...6 7 8 9...11 12 13 14...15 16...18 - -Type of relay Type A Type A Type A Type A Type A Type A Type A Type A Type A - -EXTRALARGE 1...3 4...6 7 8 9...11 12 13 14...16 17...20 21...24 25...29Type of relay Type A Type A Type A Type A Type A Type A Type A Type B Type B Type B Type B
Number of changeover contacts 1: SMALL (relay 8) 3: MEDIUM and EXTRALARGE (relay 8, 12, 13) 5: LARGE NO (relay 8, 12, 13, 14 and 15)
Note: output relays have diff erent features depending on the model of
Switchable
power
Type A relayRated data SPDT, 2000 VA, 250 Vac, 8A resistive
ApprovalUL60730 2 A resistive, 250 Vac, 30,000 cycles Pilot duty C300, 240Vac, 30,000 cyclesEN 60730-1 2(2)A, 250 Vac, 100,000 cycles
Type B relayRated data SPST, 1250 VA, 250 Vac, 5A resistive
ApprovalUL60730 1 A resistive, 250 Vac, 30,000 cycles Pilot duty C300, 240Vac, 30,000 cycles
1(1), 250 Vac, 100,000 cycles
SSR outputs (on
models where
provided)
Maximum number 1: SMALL (output 7); 2: MEDIUM-EXTRALARGE (outputs 7 and 12); 3 or 4: LARGE (outputs 7, 12, 14 or 7, 12, 14, 15)Working voltage 24 Vac/Vdc SELV 230VacLoad current (MAX) 1 A 70mAPulse load current (MAX) 1,2 A 150mA
Warning:• if the load requires a higher current, use an external SSR. To power external loads, use the same power supply as the pCO (connected to terminals G-G0); this must
always be dedicated and not in common with the power supply to other devices (e.g. contactors, coils, etc.);
• to simplify wiring, the groups of digital outputs have two common pole terminals;
• make sure that the current running through the common terminals does not exceed the rated current of each terminal, i.e. 8A.
(*) class 2
Serial ports (for +/- use AWG 20-22 twisted pair shielded cable)
Serial Type/connectors FeaturesSerial 0 pLAN/J10, J11 • Integrated on main board
• HW driver: asynchronous half duplex RS485 pLAN
• Not optically-isolated
• Connectors: 6-pin telephone jack + 3-pin plug-in, 5.08 pitch
• Maximum length: 500 m
• Max data rate: 38400 bit/s
• Maximum number of connectable devices: 32
Serial ONE BMS 1 Serial Card • Not integrated on main board
• HW driver: not present
• Can be used with all pCO family optional BMS cards
Serial TWO FieldBus 1 Serial
Card
• Not integrated on main board
• HW driver: not present
• Can be used with all pCO family optional FieldBus cards
Serial THREE BMS 2 / J25 • Integrated on main board
• HW driver: asynchronous half duplex RS485 Slave
• Optically-isolated/not optically-isolated serial (*)
• 3-pin plug-in connector, 5.08 pitch
• Maximum length: 1000 m
• Max data rate: 115200 bit/s
• Maximum number of connectable devices: 16
Serial FOUR FieldBus 2 / J26
(and J23 on Large
and Extralarge
version)
• Integrated on main board
• HW driver: asynchronous half duplex RS485 Master/Slave (**)
• J23: not optically-isolated
• J26: optically-isolated/ not optically-isolated
• 3-pin plug-in connector, 5.08 pitch
• J23 and J26 are both managed by the same protocol as serial
4, with the advantage of being electrically independent.
(*): both models are available; (**): port J26 can be confi gured: see par. 3.2.
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c.pCO +0300057EN rel. 1.0 - 19.01.2015
Note: in industrial/residential applications with distances greater than 10 m, use shielded cable with earthed shield.
In residential applications (EN 55014), regardless of cable length, in versions without valve driver, the connection cable between controller and terminal and
the serial cable must be shielded and earthed on both sides.
Ethernet RJ45 connector c.pCOmini High End one 10/100 Mbps Ethernet port
cpCO Small...Extralarge two equivalent 10/100 Mbps Ethernet ports (100-BASE TX standard)
c.pCOminiSingle-pole valve output
Number of valves: 1Maximum output for each valve 8 W
Type of control Single-pole
Valve connector 6-pin, fi xed sequence
Power supply 13 V ± 5%
Maximum current 0.35 A for each winding
Minimum winding resistance 40 Ω
Max connection cable length
Residential/industrial environments: 2 m without shielded cable, or with shielded cable earthed at both ends
(E2VCABS3U0, E2VCABS6U0)Residential environment: 2 m without shielded cable
c.pCO: Model with electronic expansion valve driverCompatible valves CAREL: E*V****
ALCO: EX4; EX5; EX6; EX7; EX8 330 Hz (recommended by CAREL); EX8 500 Hz (as per ALCO specifi cations)SPORLAN: SEI 0.5-11; SER 1.5-20; SEI 30; SEI 50; SEH 100; SEH175Danfoss: ETS 12.5-25B; ETS 50B; ETS 100B; ETS 250; ETS 400CAREL: Two CAREL EXVs as for EVD EVOLUTION TWINSPORLAN: SER(I) G, J, K
Motor connection Shielded 4-wire cable CAREL P/N E2VCABS*00, or shielded 4-wire cable AWG22 Lmax =10 m, or shielded 4-wire cable AWG14 Lmax 50
mConnection digital inputs Digital input to be activated with voltage-free contact or transistor to GND.
Closing current 5 mA; maximum length < 10 mProbes Maximum length 10 m or less than 30 m with shielded cable
Power to active probes
(VREF)
Programmable output: +5 Vdc ±2% or 12 Vdc ±10%, Imax = 50 mA
Emergency power supply Optional Ultracapacitor module (PCOS0WUC20 or EVD0000UC0). If the controller works constantly at temperatures near the upper
limit of 60°C it is recommended to use the external module P/N EVD0000UC0, if possible placed in the coolest point of the panel.
Modules PCOS0WUC20 and EVD0000UC0 can be connected to the same controller at the same time, thereby doubling the energy
available for closing the valves. Important: the module only powers the valve driver and not the controller.
Standards compliance
Electrical safety EN 60730-1, EN 60730-2-9, EN 61010-1, UL60730
Electromagnetic
compatibility
Versions without valve driver: EN 61000-6-1, EN 61000-6-2, EN 61000-6-2/EC, EN 61000-6-2/IS1, EN 61000-6-3,
EN 61000-6-4; EN 55014-1, EN 55014-2, EN 55014-2/EC, EN 55014-2/A1, EN 55014-2/IS1, EN 55014-2/A2
Versions with valve driver with or without Ultracap module: EN 61000-6-1, EN 61000-6-2,
EN 61000-6-2/EC, EN 61000-6-2/IS1, EN61000-6-3, EN 61000-6-4
c.pCO connectors
Electrical specifi cations of the plug-in connectors used:
Connector type 5.08 mm pitchCable size 0.25 mm2 - 2.5 mm2 (AWG: 24 to 12)Stripped length 7 mmScrew thread M3Tightening torque 0.5 to 0.6 Nm
Correspondence between AWG and cable cross-section
AWG Cross-section (mm2) Max current20 0.5 215 1.5 614 2.5 8
CAREL INDUSTRIES - HeadquartersVia dell’Industria, 11 - 35020 Brugine - Padova (Italy)
Tel. (+39) 049.9716611 - Fax (+39) 049.9716600
e-mail: carel@carel.com - www.carel.com
Agenzia / Agency:
c.p
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